Name: ASTM D3419-93 - Standard Practice for In-Line Screw-Injection Molding Test Specimens From Thermosetting Compounds
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Abstract

Standard Practice for In-Line Screw-Injection Molding Test Specimens From Thermosetting Compounds

SCOPE
1.1 This practice covers the general principles to be followed when injection molding test specimens of thermosetting materials. It is to be used to obtain uniformity in methods of describing the various steps of the injection molding process and in the reporting of those conditions. The exact molding conditions will vary from material to material, and should become part of the material specification or be agreed upon between the purchaser and the supplier.
Note 1--The utility of this practice has been demonstrated for the molding of thermosetting molding compounds exhibiting lower-viscosity non-Newtonian flow.
1.2 The values stated in SI units are to be regarded as the standard. The values given in parentheses are for information only.
1.3 This standard does not purport to address all of the safety problems, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety and health practices and determine the applicability of regulatory limitations prior to use.
1.3 This practice assumes the use of reciprocating screw injection molding machines.
Note 2--This standard is similar in content (but not technically equivalent) to ISO 10724: 1994(E).

General Information

Status

Historical

Publication Date

09-Nov-2000

ICS

83.140.99 - Other rubber and plastics products

Technical Committee

D20 - Plastics

Drafting Committee

D20.09 - Specimen Preparation

Current Stage

Ref Project

Relations

Replaced By

ASTM D3419-00 - Standard Practice for In-Line Screw-Injection Molding Test Specimens From Thermosetting Compounds

Effective Date

10-Nov-2000

Referred By

ASTM D6289-13(2019) - Standard Test Method for Measuring Shrinkage from Mold Dimensions of Molded Thermosetting Plastics

Effective Date

10-Nov-2000

Referred By

ASTM D5948-05(2020) - Standard Specification for Molding Compounds, Thermosetting

Effective Date

10-Nov-2000

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ASTM D3419-93 - Standard Practice for In-Line Screw-Injection Molding Test Specimens From Thermosetting Compounds

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Standards Content (Sample)

ASTM D3419-93 - Standard Pract...

NOTICE: This standard has either been superseded and replaced by a new version or discontinued.
Contact ASTM International (www.astm.org) for the latest information.
Designation: D 3419 – 93
Standard Practice for
In-Line Screw-Injection Molding Test Specimens From
Thermosetting Compounds
This standard is issued under the ﬁxed designation D 3419; the number immediately following the designation indicates the year of
original adoption or, in the case of revision, the year of last revision. A number in parentheses indicates the year of last reapproval. A
superscript epsilon (e) indicates an editorial change since the last revision or reapproval.
1. Scope for a very short period of time at an early stage in the process
of cure.
1.1 This practice covers a general procedure for screw-
3.2.2 Discussion—Breathing allows the escape of gas or
injection molding thermosetting materials into test specimens
vapor from the molding material and reduces the tendency of
for Izod or Charpy impact, ﬂexure, tension, compression,
thick moldings to blister.
water-absorption, heat-aging, electrical, modulus in tension or
3.2.3 cavity (of a mold), n—the space within a mold to be
ﬂexure, and heat-deﬂection temperature tests.
ﬁlled to form the molded product.
NOTE 1—The utility of this practice has been demonstrated for the
molding of thermosetting molding compounds exhibiting lower-viscosity
4. Signiﬁcance and Use
non-Newtonian ﬂow.
4.1 This practice is subject to the deﬁnition of injection
1.2 The values stated in SI units are to be regarded as the
molding given in 3.1.2 with the further provision that with
standard. The values given in parentheses are for information
in-line screw injection the plastic compound, heated in a
only.
chamber by conduction and friction, is ﬂuxed by the action of
1.3 This standard does not purport to address all of the
a reciprocating screw and then is forced into a hot mold where
safety problems, if any, associated with its use. It is the
it solidiﬁes. Hereafter, in-line screw-injection molding will be
responsibility of the user of this standard to establish appro-
referred to simply as injection molding.
priate safety and health practices and determine the applica-
4.2 The mold referenced in this practice provides for a set of
bility of regulatory limitations prior to use.
ﬁve specimens. However, if only certain specimens are desired,
the other cavities may be blocked by inserting gate blanks.
NOTE 2—There are no ISO standards covering the primary subject of
4.3 Typically, injection-molded test specimens are made
this practice.
with shorter cycles than those used for similar moldings made
2. Referenced Documents
by compression, and the cycle is equal to or faster than that for
2.1 ASTM Standards: transfer molding.
D 883 Terminology Relating to Plastics 4.4 Breathing of the mold is not usually required to release
D 958 Practice for Determining Temperatures of Standard trapped volatile material as the gas is free to ﬂow from the vent
ASTM Molds for Test Specimens of Plastics end of the mold. This is particularly advantageous for heat-
resistant compounds and reduces the tendency for molded
3. Terminology
specimens to blister at high exposure temperatures.
3.1 Deﬁnitions:
4.5 Injection molding is intended for low-viscosity com-
3.1.1 General—Deﬁnitions of terms applying to this prac- pounds. One set of processing parameters cannot be speciﬁed
tice appear in Terminology D 883.
for all types of thermosetting materials, nor for samples of the
3.1.2 injection molding—the process of forming a material same material having different plasticities.
by forcing it, in a ﬂuid state and under pressure, through a
4.6 Materials containing ﬁbrous ﬁllers such as glass roving,
runner system (sprue, runner, and gate(s)) into the cavity of a chopped cloth, or cellulosic ﬁbers can be injection molded, but
closed mold.
their properties will be affected depending upon how much
3.1.3 Discussion—Screw-injection molding and reaction-
ﬁber breakdown occurs as the compound is worked by the
injection molding are types of injection molding. screw and as it passes through the system of runners and gates.
3.2 Deﬁnitions of Terms Speciﬁc to This Standard:
The orientation of the ﬁbers in the molded specimen will also
3.2.1 breathing, v—the operation of opening a mold or press affect injection-molded properties.
4.7 Flow and knit lines in a molded piece are often sites of
mechanical or electrical weakness. The ﬂuxed material passing
This practice is under the jurisdiction of ASTM Committee D-20 on Plastics
through the gate wrinkles and folds as it proceeds into the mold
and is the direct responsibility of Subcommittee D20.09 on Specimen Preparation.
Current edition approved Feb. 15, 1993. Published April 1993. Originally
cavity. Knit lines may be found to some degree throughout the
published as D 3419 – 75. Last previous edition D 3419 – 92a.
molded piece; these knit lines affect end-test results. Fibers and
Annual Book of ASTM Standards, Vol 08.01.
Copyright © ASTM, 100 Barr Harbor Drive, West Conshohocken, PA 19428-2959, United States.
D 3419
other reinforcements in the molding compound align with the sufficient to maintain a uniform mold temperature within 63°C
ﬂow pattern and, consequently, may be perpendicular to the across the mold surface.
axis of the bar at its center and parallel at its surface. 5.4 Temperature Indicator—Typically, a surface pyrometer
4.8 The Izod impact strength of injection-molded specimens is used to measure the temperature of the molded surface as
containing short ﬁbers will generally be lower than the values speciﬁed in Practice D 958.
obtained using compression molding methods. The impact
6. Conditioning
strength may also vary along the axis of the bar due to molding
parameters, ﬂow patterns, and ﬁber orientation. 6.1 Store the molding compound in moisture barrier con-
4.9 The ﬂexural and tensile strength of injection-molded tainers and keep at standard room temperature at the time of
specimens of molding compounds containing short ﬁbers will molding. Compounds designed for screw-inje
...

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Section
Introduction and Background
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2.2
NFPA Standard
2.3
ASME Standards
2.4
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5.1 Heat buildup in PVC exterior building products due to absorption of the energy from the sun may lead to distortion problems. Heat buildup is affected by the color, emittance, absorptance, and reflectance of a product. Generally, the darker the color of the product, the more energy is absorbed and the greater is the heat buildup. However, even with the same apparent color, the heat buildup may vary due to the specific pigment system involved. The greatest heat buildup generally occurs in the color black containing carbon black pigment. The black control sample used in this test method contains 2.5 parts of furnace black per 100 parts of PVC suspension resin. The maximum temperature rise above ambient temperature for this black is 90°F (50°C) for a 45° or horizontal surface when the sun is perpendicular to the surface and 74°F (41°C) for a vertical surface assuming that the measurements were done on a cloudless day with no wind and heavy insulation on the back of the specimen.4
5.2 This test method allows the measurement of the temperature rise under a specific type heat lamp, relative to that of a black reference surface, thus predicting the heat buildup due to the sun's energy.
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1.1 This test method covers prediction of the heat buildup in rigid and flexible PVC building products above ambient air temperature, relative to black, which occurs due to absorption of the sun's energy.
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ABSTRACT
This specification establishes requirements for the material properties, including dimensional stability, weatherability, and extrusion quality, of rigid poly(vinyl chloride) (PVC) exterior profile extrusions used for assembled windows and doors. Methods for testing and for identifying exterior profile extrusions that comply with this specification are also provided. The physical and performance requirements of PVC are presented in details. The dimensional stability and impact strength shall be tested to meet the requirements prescribed.
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1.2 The use of rigid PVC recycled plastic in this product shall be in accordance with the requirements in Section 6.
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Note 2: Refer to Specification D3678 for interior profile extrusions.
1.3 Color-hold guidelines are provided in an appendix for the manufacturer’s product development and quality performance use.
1.4 Color-hold guidelines are presently limited to white, grey, beige, light brown, and dark brown (see Figs. X1.1 through X1.5). Additional colors will be added as color guidelines are developed.
1.5 The values stated in inch-pound units are to be regarded as standard. The values given in parentheses are for information only.
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1.6 The text of this standard references notes and footnotes, which provide explanatory material. These notes and footnotes (excluding those in tables and figures) shall not be considered as requirements of this standard.
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Note 2: There is no known ISO equivalent to this standard.
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5.1 These procedures provide a means to assess the drop impact resistance of the group or lot of blown containers from which the test specimens were selected.
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1.3 The values stated in SI units are to be regarded as standard. The inch-pound units given in parentheses are for information only.
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1.4 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.
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This specification covers requirements and methods of test for the material, dimensions, and workmanship, and the properties of extruded, compression molded, and injection molded PAEK sheet, plate, rod, and tubular bar manufactured from PAEK. The type of PAEK extruded, compression molded, and injection molded product may be categorized by type, grade and class depending on resin and filler compositions. Every type of PAEK shape may be categorized into one of several grades as follows: Grade 1 (general purpose) which is extruded, compression molded or injection molded product made using only 100% virgin PAEK resin and Grade 2 (recycle grade) which is extruded, compression molded or injection molded product made using any amount up to 100% of recycled thermoplastic PAEK. The type, class and grade is further differentiated based on dimensional stability. Different tests shall be conducted in order to determine the following properties of PAEK: tensile stress at break, elongation at break, tensile modulus, dimensional stability, lengthwise camber and widthwise bow, squareness, flexural modulus, and Izod impact.
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1.1 This specification covers requirements for the PAEK materials used and the requirements and methods of test for the dimensions, workmanship, and the properties of extruded, compression molded, and injection molded PAEK sheet, plate, rod, and tubular bar manufactured from PAEK. PAEK is a family of thermoplastic materials that differ in properties (see Section 3).
1.2 The properties included in this specification are those required for the compositions covered. Requirements necessary to identify particular characteristics important to specialized applications are described by using the classification system given in Section 4.
1.3 This specification allows the use of key clad plastics (see Section 4).
1.4 The values are stated in inch-pound units and are regarded as the standard in all property and dimensional tables. For reference purposes, SI units are also included in Table 1.
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1.1 This classification system covers requirements for plasticized cellulose acetate butyrate thermoplastic compounds suitable for injection molding and extrusion. These compounds have a butyryl content less than 38 % and an acetyl content less than 15 % and can contain dyes and pigments. This classification system does not include special materials compounded for special applications. Cellulosic plastic materials, being thermoplastic, are reprocessable and recyclable. This classification system allows for the use of those cellulosic materials, provided that all specific requirements of this classification system are met.
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1.3 This classification system and subsequent line call out (specification) are intended to provide a means of calling out plastic materials used in the fabrication of end items or parts. It is not intended for the selection of materials. Material selection can be made by those having expertise in the plastic field only after careful consideration of the design and performance required of the part, environment to which it will be exposed, fabrication process to be employed, costs involved, and inherent properties of the material other than those covered by this classification system.
1.4 The values stated in SI units are to be regarded as standard.
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Standard Specification for Polymeric Piles

ABSTRACT
This specification establishes the physical and performance requirements for round and rectangular cross-section polymeric piles in axial and lateral load-bearing applications including, by not limited to, marine, waterfront, and corrosive environments. It does not apply to individual polymeric pile products, sheet piles, and other mechanically connected polymeric pile products using inter-locking systems. Covered here are six types of polymeric piles that are fabricated from materials that may be virgin, recycled, or both, as long as the finished product meets all of the criteria specified herein. These types are: Type I, polymeric only; Type II, polymeric with reinforcement in the form of chopped, milled or continuous fiber or mineral; Type III, polymeric with reinforcement in the form of metallic bars, cages, or shapes; Type IV, polymeric with reinforcement in the form of non-metallic bars or cages; Type V, polymeric composite tube with a concrete core; and Type VI, any other polymeric piling meeting the requirements stated herein and not otherwise described by Types I through V. The polymeric tiles shall adhere to specified physical attributes such as size, cross-sectional shape, length, straightness, placement of reinforcement, and surface conditions. The performance requirements which pile specimens shall conform to include creep rupture, serviceability, flexural properties, shear strength, bearing strength, design flexural stiffness, energy absorption, compressive strength, combined stresses, dimensional stability (thermal expansion), hygrothermal cycling, and flame spread index.
SCOPE
1.1 This specification addresses the use of round and rectangular cross-section polymeric piles in axial and lateral load-bearing applications, including but not limited to marine, waterfront, and corrosive environments.
1.2 This specification is only applicable to individual polymeric pile products. Sheet pile and other mechanically connected polymeric pile products using inter-locking systems, are not part of this specification.
1.3 The piling products considered herein are characterized by the use of polymers, whereby (1) the pile strength or stiffness requires the inclusion of the polymer, or (2) a minimum of fifty percent (50 %) of the weight or volume is derived from the polymer. The type classifications of polymeric piles described in Section 4 show how they can be reinforced by composite design for increased stiffness or strength.
1.4 This specification covers polymeric piles fabricated from materials that are virgin, recycled, or both, as long as the finished product meets all of the criteria specified herein. Diverse types and combinations of inorganic filler systems are permitted in the manufacturing of polymeric piling products. Inorganic fillers include such materials as talc, mica, silica, wollastonite, calcium carbonate, etc. Pilings are often placed in service where they will be subjected to continuous damp or wet exposure conditions. Due to concerns of water sensitivity and possible affects on mechanical properties in such service conditions, organic fillers, including lignocellulosic materials such as those made or derived from wood, wood flour, flax shive, rice hulls, wheat straw, and combinations thereof, are not permitted in the manufacturing of polymeric piling products.
1.5 The values are stated in inch-pound units as these are currently the most common units used by the construction industry.
1.6 Polymeric piles under this specification are designed using design stresses determined in accordance with Test Methods D6108, D6109, and D6112 and procedures contained within this specification unless otherwise specified.
1.7 Although in some instances it will be an important component of the pile design, frictional properties are currently beyond the scope of this document.
1.8 Criteria for design are included as part of this specification for polymeric piles. Certain Types and...

Technical specification
18 pages
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Technical specification
18 pages
English language
sale 15% off

31-Jan-2023
83.140.99
D20

ASTM

ASTM D7486-22(Test Method)

Standard Test Method for Measurement of Fines and Dust Particles on Plastic Pellets by Wet Analysis

SIGNIFICANCE AND USE
5.1 Molding and extruding plastic pellets require dust free, dry pellets to prevent processing problems. Plastic producers try to remove the dust and streamers with dust removal systems prior to packaging and loading. How to accurately measure dust and streamer content in plastic pellets is an important quality control issue.
5.2 Particle size analysis is used to determine a percentage of particle size distribution from a representative sample of the whole. In terms of size analysis concerning plastic pellets, sieving is used to determine the dust content in the range of 500 to 2000 micron. Test Method D1921, Test Method B, is used to determine this type of particle sizing.
5.3 After dry sieve analysis, particles smaller than 500 microns need to be analyzed by wet method. A fresh sample shall be used for wet analysis. This test method allows washing down the fines attached to the pellets by electrostatic forces.
5.4 The wet analysis provides accurate quantification of small to large amounts of fines, negating static effects, and eliminating detrimental effects of mechanical agitation. A wet analysis must be employed to accurately quantify lower PPM dust levels in plastic pellets.
SCOPE
1.1 This test method measures the amount of fine particles adhered on plastic pellets or granules in which they are commonly produced and supplied. The lower limit of this test method is restricted only by the porosity of the filter disc used to capture the particle size being quantified.
1.2 The wet analysis technique allows for separation and collection of statically charged particles by liquid wash and filtration methods. This must be performed under standard laboratory conditions.
1.3 The values stated in SI units are to be regarded as standard.
1.4 This test method describes an essential practice to check the quality of plastics once the production cycle is terminated and to evaluate the performance of pellet cleaning systems or of the special pneumatic conveying systems for the distinct size fractions below 500 micron only.
1.5 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.
Note 1: There is no known ISO equivalent to this standard.
1.6 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

Standard
5 pages
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Standard
5 pages
English language
sale 15% off

31-Oct-2022
83.140.99
D20