Difference between revisions of "Rods/Pipes"

From CAMEO
Jump to navigation Jump to search
 
(2 intermediate revisions by the same user not shown)
Line 2: Line 2:
 
A rod is classically defined as a thin, straight cylindrical bar of material, usually wood or metal. In the 20th century, plastics became the the material of choice for most rods as they were readily available and light weight. New plastic materials offer strength and stiffness comparable to steel, and innovative processing capabilities allow us to machine plastic parts with tight tolerances. Combined with other benefits, many industries – particular medical and aerospace – are replacing their metal parts with plastic.  
 
A rod is classically defined as a thin, straight cylindrical bar of material, usually wood or metal. In the 20th century, plastics became the the material of choice for most rods as they were readily available and light weight. New plastic materials offer strength and stiffness comparable to steel, and innovative processing capabilities allow us to machine plastic parts with tight tolerances. Combined with other benefits, many industries – particular medical and aerospace – are replacing their metal parts with plastic.  
  
For art conservation, small and flexible tubes are mainly used as padding and interleaf over monofilament thread or metal rod mounts. Examples of tubing include heat-shrinkable tubing (made of Teflon, polyethylene or polypropylene) on metal wire, or silicone and polyethylene (surgical) tubing over monofilament lines to provide padding at points of contact. Polyethylene foam tubes and foam cylinders, sold typically as insulation to cover metal pipes, can also be used as padding and support in a variety of museum applications. Large and rigid tubes or rods are used primarily for display and for storing rolled flat textiles and similar objects. Tubing made of flexible PVC, vulcanized rubber or any rubber containing sulfur compounds should not be used.
+
For art conservation, small and flexible tubes are mainly used as padding and interleaf over monofilament thread or metal rod mounts. Examples of tubing include heat-shrinkable tubing (made of [[Teflon]], [[polyethylene]] or [[polypropylene]]) on metal wire, or [[Silicone resin|silicone]] and polyethylene (surgical) tubing over monofilament lines to provide padding at points of contact. Polyethylene foam tubes and foam cylinders, sold typically as insulation to cover metal pipes, can also be used as padding and support in a variety of museum applications. Large and rigid tubes or rods are used primarily for display and for storing rolled flat textiles and similar objects. Tubing made of flexible [[Polyvinyl chloride|PVC]] ([[Tygon]]), [[vulcanized rubber]] or any rubber containing sulfur compounds should not be used.
  
 
A plastic rod is a solid plastic shape generally made by the process of plastic extrusion.  Most plastic rods fall into the category of thermoplastic that can be reheated and harden when they cool. Thermoplastics have a wide range of properties and can be recycled.  In contrast thermosets, can not be reshaped when heated and are not recyclable.  However, the structural integrity of thermosets and their resistance to chemicals often make them preferable over metals because they have a higher strength to weight ratio. Thermosets are often used in composites.  Due to the wide variety of plastics currently used in the production of plastic rods, the table below has been created to show some of their variations.
 
A plastic rod is a solid plastic shape generally made by the process of plastic extrusion.  Most plastic rods fall into the category of thermoplastic that can be reheated and harden when they cool. Thermoplastics have a wide range of properties and can be recycled.  In contrast thermosets, can not be reshaped when heated and are not recyclable.  However, the structural integrity of thermosets and their resistance to chemicals often make them preferable over metals because they have a higher strength to weight ratio. Thermosets are often used in composites.  Due to the wide variety of plastics currently used in the production of plastic rods, the table below has been created to show some of their variations.
Line 9: Line 9:
 
|-
 
|-
 
! Materials
 
! Materials
! tensile strength (psi)
+
! Tensile strength (psi)
 
! Density (g/cm3)
 
! Density (g/cm3)
 
! Fabrication
 
! Fabrication
Line 16: Line 16:
 
| colspan="5" | '''''Thermoplastic'''''
 
| colspan="5" | '''''Thermoplastic'''''
 
|-
 
|-
| ABS  (Acrylonitrile-Butadiene-Styrene)
+
| [[Acrylonitrile butadiene styrene|Acrylonitrile-Butadiene-Styrene]] (ABS)
 
| 4,100
 
| 4,100
 
| 1.04
 
| 1.04
Line 22: Line 22:
 
| Low cost engineering plastic with  good impact resistance and strength. Used for tubes and rods
 
| Low cost engineering plastic with  good impact resistance and strength. Used for tubes and rods
 
|-
 
|-
| Acetal  (Delrin, polyoxymethylene)
+
| [[Acetal resin|Acetal]]   ([[Delrin]], polyoxymethylene)
 
| 10,000
 
| 10,000
 
| 1.42
 
| 1.42
Line 28: Line 28:
 
| High-strength, semi-crystalline  with low absorption in moisture; resistant to solvents
 
| High-strength, semi-crystalline  with low absorption in moisture; resistant to solvents
 
|-
 
|-
| Acrylic  (Plexiglas)
+
| [[Acrylic resin|Acrylic]]   ([[Plexiglas]])
 
| 10,000
 
| 10,000
 
| 1.19
 
| 1.19
 
| Cast rods have better optical  clarity and machinability than extruded rods, but also more costly
 
| Cast rods have better optical  clarity and machinability than extruded rods, but also more costly
| Strong, stiff, with glass-like  properties (clarity, transparency, and brilliance), but it is half the weight  and more times the impact resistance of glass  
+
| Strong, stiff, with glass-like  properties (clarity, transparency, and brilliance), but it is half the weight  and has much more impact resistance than glass  
 
|-
 
|-
| Nylon
+
| [[Nylon]]
 
| 12,400
 
| 12,400
 
| 1.14
 
| 1.14
Line 40: Line 40:
 
| Stiff and strong engineering  plastic containing outstanding wear and abrasion resistance; should be ne  used for extened outdoor service
 
| Stiff and strong engineering  plastic containing outstanding wear and abrasion resistance; should be ne  used for extened outdoor service
 
|-
 
|-
| Polyamide  imide (PAI)
+
| [[Polyamide-imide|Polyamide  imide]] (PAI)
 
| 21,000
 
| 21,000
 
| 1.41
 
| 1.41
 
| Easy to fabricate and weld using  thermoplastic welding equipment
 
| Easy to fabricate and weld using  thermoplastic welding equipment
| good wear and radiation  resistance, inherently low flammability and smoke emission, and high thermal  stability. The highest strength of any unreinforced thermoplastic,
+
| Good wear and radiation  resistance, inherently low flammability and smoke emission, and high thermal  stability. The highest strength of any unreinforced thermoplastic,
 
|-
 
|-
| Polycarbonate
+
| [[Polycarbonate]]
 
| 9,500
 
| 9,500
 
| 1.20
 
| 1.20
Line 52: Line 52:
 
| Semi-transparent, stiff, and  strong with outstanding impact resistance and low moisture absorption.
 
| Semi-transparent, stiff, and  strong with outstanding impact resistance and low moisture absorption.
 
|-
 
|-
| Polyethylene  (HDPE)
+
| [[Polyethylene]]   (HDPE)
 
| 4,000
 
| 4,000
 
| 0.96
 
| 0.96
Line 58: Line 58:
 
| High-density polyethylene is a  chemically resistant, strong, durable, lightweight plastic material
 
| High-density polyethylene is a  chemically resistant, strong, durable, lightweight plastic material
 
|-
 
|-
| Polyetheretherketone  (PEEK)
+
| [[Polyetheretherketone]]   (PEEK)
 
| 14,000
 
| 14,000
 
| 1.32
 
| 1.32
Line 64: Line 64:
 
| Very high mechanical strength  and dimensional stability (similar to Delrin, PTFE and Nylon)
 
| Very high mechanical strength  and dimensional stability (similar to Delrin, PTFE and Nylon)
 
|-
 
|-
| Polyphenylene  sulfide PPS
+
| [[Polyphenylene sulfide|Polyphenylene  sulfide]] (PPS)
 
| 12,500
 
| 12,500
 
| 1.35
 
| 1.35
 
| Easy to fabricate and weld using  thermoplastic welding equipment
 
| Easy to fabricate and weld using  thermoplastic welding equipment
| heat resistance, dimensional  stability, rigidity, chemical resistance, flame retardance, and moist-heat  resistance. It is also resistant to acids, alkalis, mildew, bleaches, aging,  sunlight, and abrasion
+
| Good heat resistance, dimensional  stability, rigidity, chemical resistance, flame retardance, and moist-heat  resistance. It is also resistant to acids, alkalis, mildew, bleaches, aging,  sunlight, and abrasion
 
|-
 
|-
| Polypropylene
+
| [[Polypropylene]]
 
| 5,400
 
| 5,400
 
| 0.91
 
| 0.91
Line 76: Line 76:
 
| Chemically resistant plastic rod  with excellent aesthetic properties at a cost that is low. The polypropylene  plastic rod is easy to weld using thermoplastic welding equipment,
 
| Chemically resistant plastic rod  with excellent aesthetic properties at a cost that is low. The polypropylene  plastic rod is easy to weld using thermoplastic welding equipment,
 
|-
 
|-
| Polytetrafluoroethylene  PTFE (Teflon)
+
| [[Polytetrafluoroethylene]] (PTFE, [[Teflon]])
 
| 1,500-3,000
 
| 1,500-3,000
 
| 2.15
 
| 2.15
 
| Easy to fabricate and weld using  thermoplastic welding equipment; adhesion is difficult
 
| Easy to fabricate and weld using  thermoplastic welding equipment; adhesion is difficult
| soft, low friction fluoropolymer  rod that has outstanding resistance to weathering and chemicals
+
| Soft, low friction fluoropolymer  rod that has outstanding resistance to weathering and chemicals
 
|-
 
|-
| Polyurethane
+
| [[Polyurethane]]
 
|  
 
|  
 
|  
 
|  
Line 88: Line 88:
 
| can be bonded to metals fabrics  and other plastics
 
| can be bonded to metals fabrics  and other plastics
 
|-
 
|-
| PVC  (Polyvinyl chloride, Vinyl)
+
| [[Polyvinyl chloride]] (PVC, Vinyl, [[Tygon]])
 
|  
 
|  
 
| 1.42
 
| 1.42
 
| Easy to fabricate and weld using  thermoplastic welding equipment
 
| Easy to fabricate and weld using  thermoplastic welding equipment
| strong and stiff; low-cost  plastic material that is easy to fabricate and easy to bond using solvents  and adhesives. The polyvinyl chloride plastic rod is also easy to weld using  thermoplastic welding
+
| Strong and stiff; low-cost  plastic material that is easy to fabricate and easy to bond using solvents  and adhesives. The polyvinyl chloride plastic rod is also easy to weld using  thermoplastic welding
 
|-
 
|-
 
| Ultem  (Polyetherimide, PEI)
 
| Ultem  (Polyetherimide, PEI)
Line 98: Line 98:
 
| 1.27
 
| 1.27
 
| Can be drilled, cut, sawed,  sanded, maintains close tolerances
 
| Can be drilled, cut, sawed,  sanded, maintains close tolerances
| properties similar to PEEK, but  with a lower impact strength and usable temperature as well as a lower cost;  excellent flame resistance
+
| Properties similar to PEEK, but  with a lower impact strength and usable temperature as well as a lower cost;  excellent flame resistance
 
|-
 
|-
 
| colspan="5" | '''''Thermoset'''''
 
| colspan="5" | '''''Thermoset'''''
 
|-
 
|-
| Fiberglass  reinforced plastic (FRP)
+
| [[Fiberglass |Fiberglass]]   reinforced plastic (FRP)
 
| 30,000
 
| 30,000
 
| 1.07-1.20
 
| 1.07-1.20
 
| Can be drilled, cut, sawed,  sanded, maintains close tolerances
 
| Can be drilled, cut, sawed,  sanded, maintains close tolerances
| thermoset; rigid polyester  matrix reinforced with glass fibers; good insulator with low thermal  conductivity; not electrically conductive
+
| Thermoset; rigid polyester  matrix reinforced with glass fibers; good insulator with low thermal  conductivity; not electrically conductive
 
|-
 
|-
| Filled  phenolic
+
| Filled  [[Phenolic resin|phenolic]]
 
| 11,500
 
| 11,500
 
| 1.35
 
| 1.35
Line 114: Line 114:
 
| Can  visually look appear like wood or metal;  may emit formaldehyde
 
| Can  visually look appear like wood or metal;  may emit formaldehyde
 
|-
 
|-
| Reinforced  epoxy (FR-4 Glass Epoxy)
+
| Reinforced  [[Epoxy|epoxy]] (FR-4 Glass Epoxy)
 
| 38,000
 
| 38,000
 
| 1.8
 
| 1.8
Line 122: Line 122:
 
| colspan="5" | '''''Other'''''
 
| colspan="5" | '''''Other'''''
 
|-
 
|-
| Aluminum  6061-T6
+
| [[Aluminum]]   6061-T6
 
| 45,000
 
| 45,000
 
| 2.70
 
| 2.70
 
| Good machinability
 
| Good machinability
| can cause galvanic corrosion;  easily deforms under impact
+
| Can cause galvanic corrosion;  easily deforms under impact
 
|-
 
|-
| Copper
+
| [[Copper]]
 
| 28,000
 
| 28,000
 
| 8.93
 
| 8.93
 
| Good machinability
 
| Good machinability
| subject to oxidation and   corrosion
+
| May oxidize and/or corrode
 
|-
 
|-
| Brass
+
| [[Brass]]
 
| 45,000
 
| 45,000
 
| 8.5-8.8
 
| 8.5-8.8
 
| Good machinability
 
| Good machinability
| subject to oxidation and   corrosion
+
| May oxidize and/or corrode
 
|-
 
|-
| Stainless  Steel 304
+
| [[Stainless steel|Stainless  Steel]] 304
 
| 90,000
 
| 90,000
 
| 7.7-8.0
 
| 7.7-8.0
 
| May require welding or cutting  torches
 
| May require welding or cutting  torches
| subject to oxidation and   corrosion; requires painting or galvanizing; can permanently deform under  impact
+
| May oxidize and/or corrode; requires painting or galvanizing; can permanently deform under  impact
 
|-
 
|-
| Glass
+
| [[Glass]]
 
| 1,000
 
| 1,000
 
| 2.4-2.8
 
| 2.4-2.8
Line 152: Line 152:
 
| Transparent, stable in most  environments
 
| Transparent, stable in most  environments
 
|-
 
|-
| Wood
+
| [[Wood]]
 
| 12,000
 
| 12,000
 
| 0.48
 
| 0.48
Line 158: Line 158:
 
| Can warp, rot and decay,  susceptible to attack by insects; low thermal conductivity; may emit acidic  vapors when drying
 
| Can warp, rot and decay,  susceptible to attack by insects; low thermal conductivity; may emit acidic  vapors when drying
 
|}
 
|}
 
  
 
== Synonyms and Related Terms ==
 
== Synonyms and Related Terms ==

Latest revision as of 10:08, 2 May 2023

Description

A rod is classically defined as a thin, straight cylindrical bar of material, usually wood or metal. In the 20th century, plastics became the the material of choice for most rods as they were readily available and light weight. New plastic materials offer strength and stiffness comparable to steel, and innovative processing capabilities allow us to machine plastic parts with tight tolerances. Combined with other benefits, many industries – particular medical and aerospace – are replacing their metal parts with plastic.

For art conservation, small and flexible tubes are mainly used as padding and interleaf over monofilament thread or metal rod mounts. Examples of tubing include heat-shrinkable tubing (made of Teflon, Polyethylene or Polypropylene) on metal wire, or silicone and polyethylene (surgical) tubing over monofilament lines to provide padding at points of contact. Polyethylene foam tubes and foam cylinders, sold typically as insulation to cover metal pipes, can also be used as padding and support in a variety of museum applications. Large and rigid tubes or rods are used primarily for display and for storing rolled flat textiles and similar objects. Tubing made of flexible PVC (Tygon), Vulcanized rubber or any rubber containing sulfur compounds should not be used.

A plastic rod is a solid plastic shape generally made by the process of plastic extrusion. Most plastic rods fall into the category of thermoplastic that can be reheated and harden when they cool. Thermoplastics have a wide range of properties and can be recycled. In contrast thermosets, can not be reshaped when heated and are not recyclable. However, the structural integrity of thermosets and their resistance to chemicals often make them preferable over metals because they have a higher strength to weight ratio. Thermosets are often used in composites. Due to the wide variety of plastics currently used in the production of plastic rods, the table below has been created to show some of their variations.

Materials Tensile strength (psi) Density (g/cm3) Fabrication Comments
Thermoplastic
Acrylonitrile-Butadiene-Styrene (ABS) 4,100 1.04 Easy to machine, can be welded (ultrasonic and thermal); easy to paint or glue Low cost engineering plastic with good impact resistance and strength. Used for tubes and rods
Acetal (Delrin, polyoxymethylene) 10,000 1.42 Can be drilled, cut, sawed, sanded, maintains close tolerances High-strength, semi-crystalline with low absorption in moisture; resistant to solvents
Acrylic (Plexiglas) 10,000 1.19 Cast rods have better optical clarity and machinability than extruded rods, but also more costly Strong, stiff, with glass-like properties (clarity, transparency, and brilliance), but it is half the weight and has much more impact resistance than glass
Nylon 12,400 1.14 Easy to fabricate, lightweight Stiff and strong engineering plastic containing outstanding wear and abrasion resistance; should be ne used for extened outdoor service
Polyamide imide (PAI) 21,000 1.41 Easy to fabricate and weld using thermoplastic welding equipment Good wear and radiation resistance, inherently low flammability and smoke emission, and high thermal stability. The highest strength of any unreinforced thermoplastic,
Polycarbonate 9,500 1.20 Can be drilled, cut, sawed, sanded, maintains close tolerances; easy to join with adhesives Semi-transparent, stiff, and strong with outstanding impact resistance and low moisture absorption.
Polyethylene (HDPE) 4,000 0.96 Easy to fabricate and weld using thermoplastic welding equipment High-density polyethylene is a chemically resistant, strong, durable, lightweight plastic material
Polyetheretherketone (PEEK) 14,000 1.32 Readily machined maintaining close tolerances Very high mechanical strength and dimensional stability (similar to Delrin, PTFE and Nylon)
Polyphenylene sulfide (PPS) 12,500 1.35 Easy to fabricate and weld using thermoplastic welding equipment Good heat resistance, dimensional stability, rigidity, chemical resistance, flame retardance, and moist-heat resistance. It is also resistant to acids, alkalis, mildew, bleaches, aging, sunlight, and abrasion
Polypropylene 5,400 0.91 Easy to fabricate and weld using thermoplastic welding equipment Chemically resistant plastic rod with excellent aesthetic properties at a cost that is low. The polypropylene plastic rod is easy to weld using thermoplastic welding equipment,
Polytetrafluoroethylene (PTFE, Teflon) 1,500-3,000 2.15 Easy to fabricate and weld using thermoplastic welding equipment; adhesion is difficult Soft, low friction fluoropolymer rod that has outstanding resistance to weathering and chemicals
Polyurethane Easy to fabricate and weld using thermoplastic welding equipment can be bonded to metals fabrics and other plastics
Polyvinyl chloride (PVC, Vinyl, Tygon) 1.42 Easy to fabricate and weld using thermoplastic welding equipment Strong and stiff; low-cost plastic material that is easy to fabricate and easy to bond using solvents and adhesives. The polyvinyl chloride plastic rod is also easy to weld using thermoplastic welding
Ultem (Polyetherimide, PEI) 15,200 1.27 Can be drilled, cut, sawed, sanded, maintains close tolerances Properties similar to PEEK, but with a lower impact strength and usable temperature as well as a lower cost; excellent flame resistance
Thermoset
Fiberglass reinforced plastic (FRP) 30,000 1.07-1.20 Can be drilled, cut, sawed, sanded, maintains close tolerances Thermoset; rigid polyester matrix reinforced with glass fibers; good insulator with low thermal conductivity; not electrically conductive
Filled phenolic 11,500 1.35 Machines readily with excellent dimensional stability Can visually look appear like wood or metal; may emit formaldehyde
Reinforced Epoxy (FR-4 Glass Epoxy) 38,000 1.8
Other
Aluminum 6061-T6 45,000 2.70 Good machinability Can cause galvanic corrosion; easily deforms under impact
Copper 28,000 8.93 Good machinability May oxidize and/or corrode
Brass 45,000 8.5-8.8 Good machinability May oxidize and/or corrode
Stainless Steel 304 90,000 7.7-8.0 May require welding or cutting torches May oxidize and/or corrode; requires painting or galvanizing; can permanently deform under impact
Glass 1,000 2.4-2.8 May splinter or shatter Transparent, stable in most environments
Wood 12,000 0.48 Easily fabricated, joined and adhered Can warp, rot and decay, susceptible to attack by insects; low thermal conductivity; may emit acidic vapors when drying

Synonyms and Related Terms

dowel; stick; pole; wand; staff,

Resources and Citations