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Military shipping container being drop tested

Testing modified atmosphere in a plastic bag of carrots

Package testing or packaging testing involves the measurement of a characteristic or property involved with packaging. This includes packaging materials, packaging components,^[1] primary packages, shipping containers, and unit loads, as well as the associated processes.

Testing measures the effects and interactions of the levels of packaging, the package contents, external forces, and end-use.

It can involve controlled laboratory experiments, subjective evaluations by people, or field testing. Documentation is important: formal test method, test report, photographs, video, etc.

Testing can be a qualitative or quantitative procedure. Package testing is often a physical test. With some types of packaging such as food and pharmaceuticals, chemical tests are conducted to determine suitability of food contact materials. Testing programs range from simple tests with little replication to more thorough experimental designs.

Package testing can extend for the full life cycle. Packages can be tested for their ability to be recycled and their ability to degrade as surface litter, in a sealed landfill or under composting conditions.^[2]

Purposes

Packaging testing might have a variety of purposes, such as:

Determine if, or verify that, the requirements of a specification, regulation, or contract are met

Decide if a new product development program is on track: Demonstrate proof of concept

Provide standard data for other scientific, engineering, and quality assurance functions

Validate suitability for end-use

Provide a basis for technical communication

Provide a technical means of comparison of several options

Provide evidence in legal proceedings: product liability, patents, product claims, etc.

Help solve problems with current packaging

Help identify potential cost savings in packaging

Packaging tests can be used for:

Subjecting packages (and contents) to stresses and dynamics found in the field

Reproducing the types of damage to packages and contents found in actual shipments

Controlling the uniformity of production of packages or components

Importance of testing

Testing the ability of packages to resist insect infestation^[3]

For some types of products, package testing is mandated by regulations: food. pharmaceuticals, medical devices, dangerous goods, etc. This may cover both the design qualification, periodic retesting, and control of the packaging processes. Processes may be controlled by a variety of quality management systems such as HACCP, statistical process control, validation protocols, ISO 9000, etc.

For unregulated products, testing can be required by a contract or governing specification. The degree of package testing can often be a business decision. Risk management may involve factors such as

costs of packaging

costs of package testing

value of contents being shipped

value of customer’s good will

product liability exposure

other potential costs of inadequate packaging

etc.

With distribution packaging, one vital packaging development consideration is to determine if a packaged-product is likely to be damaged in the process of getting to the final customer. A primary purpose of a package is to ensure the safety of a product during transportation and storage. If a product is damaged during this process, then the package has failed to accomplish a primary objective and the customer will either return the product or be unlikely to purchase the product altogether.^[4]

Package testing is often a formal part of Project management programs. Packages are usually tested when there is a new packaging design, a revision to a current design, a change in packaging material, and various other reasons. Testing a new packaging design before full scale manufacturing can save time and money.^[5]

Laboratory affiliation

Many suppliers or vendors offer limited material and package testing as a free service to customers. It is common for packagers to partner with reputable suppliers: Many suppliers have certified quality management systems such as ISO 9000 or allow customers to conduct technical and quality audits. Data from testing is commonly shared. There is sometimes a risk that supplier testing may tend to be self-serving and not completely impartial.

Large companies often have their own packaging staff and a package testing and development laboratory. Corporate engineers know their products, manufacturing capabilities, logistics system, and their customers best. Cost reduction of existing products and cost avoidance for new products have been documented.^[6]

Another option is to use a paid consultant, Independent contractor, and third-party independent testing laboratory. They are commonly chosen for specialized expertise, for access to certain test equipment, for surge projects, or where independent testing is otherwise required. Many have certifications and accreditations: ISO 9000, ISO/IEC 17025, and various governing agencies.

Procedures

Several standards organizations publish test methods for package testing. Included are:

International Organization for Standardization, ISO

ASTM International

European Committee for Standardization. CEN

TAPPI

Military Standards^[7]

ISTA (International Safe Transit Association)

etc.

Governments and regulators publish some packaging test methods. There are also many corporate test standards in use. A review of technical literature and patents provides good options to consider for test procedures.

Researchers are not restricted to the use of published standards but can modify existing test methods or develop procedures specific to their particular needs. If a test is conducted with a deviation from a published test method or if a new method is employed, the test report must fully disclose the procedure.

Materials testing

Materials and components are often evaluated on a universal testing machine

The basis of packaging design and performance is the component materials. The physical properties, and sometimes chemical properties, of the materials need to be communicated to packaging engineers to aid in the design process. Suppliers publish data sheets and other technical communications that include the typical or average relevant physical properties and the test method these are based upon. Sometimes these are adequate. Other times, additional material and component testing is required by the packager or supplier to better define certain characteristics.

When a final package design is complete, the specifications for the component materials needs to be communicated to suppliers. Packaging materials testing is often needed to identify the critical material characteristics and engineering tolerances. These are used to prepare and enforce specifications.

For example, shrink film data might include: tensile strength (MD and CD), elongation, Elastic modulus, surface energy, thickness, Moisture vapor transmission rate, Oxygen transmission rate, heat seal strength, heat sealing conditions, heat shrinking conditions, etc. Average and process capability are often provided. The chemical properties related for use as Food contact materials may be necessary.

Testing with people

Some types of package testing do not use scientific instruments but use people for the evaluation.

The regulations for child-resistant packaging require a test protocol that involves children. Samples of the test packages are given to a prescribed population of children. With specified 50-child panels, a high percentage must be unable to open a test package within 5 minutes.^[8]
Adults are also tested for their ability to open a child-resistant package.

Consumer packages are often evaluated by focus groups. People evaluate the package features in a room monitored by video cameras. The consumer responses are treated qualitatively for feedback into the new packaging process.

Some food packagers use organoleptic evaluations. People use their senses (taste, smell, etc.) to determine if a package component has tainted the food in the package.

A new package may be evaluated in a test market that uses people to try the packages at home. Consumers have the opportunity to buy a product, perhaps with a coupon or discount. Return postcards or Internet sites provide feedback to package developers. Perhaps the most critical feedback is repeated sales items in the new package. Packaging evaluations are an important part of marketing research.

Legibility of text on packaging and labels is always subjective due to the inherent variations of people. Efforts have been made to help better quantify this by people in a laboratory: still using people for the evaluation but also employing a test apparatus to help reduce variability.^[9]^[10]

Some laboratory tests are conducted but still result in an observation by people. Some test procedures call for a judgment by test engineers whether or not pre-established acceptance criteria have been met.

Relevant standards

ASTM D7298 Test Method for Measurement of Comparative Legibility by Means of Polarizing Filter Instrumentation.

ASTM E460 Practice for Determining Effect of Packaging on Food and Beverage Products During Storage

ASTM E619 Practice for Evaluating Foreign Odors in Paper Packaging

ASTM E1870 Test Method for Odor and Taste Transfer from Polymeric Packaging Film

ASTM 2609 Test Method for Odor and Flavor Transfer from Rigid Polymeric Packaging

ISO 16820 Sensory Analysis – Methodology – Sequential Analysis

ISO 5495 Sensory Analysis – Methodology – Paired Comparisons

ISO 13302 Sensory Analysis – Methods for assessing modifications to the flavour of foodstuffs due to packaging

Conditioning, testing atmosphere

Environmental chamber to simulate temperatures and humidities encountered by packages

The environmental conditions of testing are critical. The measured performance of many packages is affected by the conditioning and testing atmospheres. For example, paper based products are strongly affected by their moisture content: Relative humidity needs to be controlled. Plastic products are often strongly affected by temperature.^[11]

Conditions of 23 °C (73.4 °F) and 50% relative humidity are common but other standard testing conditions are also published in material and package test standards. Engineering tolerances for the conditions are also specified. Often the package is conditioned to the specified environment and tested under those conditions. This can be in a conditioned room or in a chamber enclosing the test. With some testing, the package is conditioned to a specified environment, then is removed to ambient conditions and quickly tested. The test report needs to state the actual conditions used.

Engineers have found it important to know the effects of the full range of expected conditions on package performance. This can be through investigating published technical literature, obtaining supplier documentation, or by conducting controlled tests at diverse conditions.

Relevant Standards

ASTM D4332- Standard Practice for Conditioning Containers, Packages, or Packaging Components for Testing

ASTM E171- Standard Specification for Standard Atmospheres for Conditioning and Testing Flexible Barrier Materials

ASTM F2825 Standard Practice for Climate Stressing of Packaging Systems for Single Parcel Delivery

Degradation of product

Heat sealer used to prepare bag of lettuce for shelf life testing

Laboratory tests can help determine the shelf life of a package and its contents under a variety of conditions. This is particularly important for foods, pharmaceuticals, some chemicals, and a variety of products. The testing is usually product specific: the mechanisms of degradation are often different. Exposures to expected and elevated temperatures and humidities are commonly used for shelf life testing. The ability of packaging to control product degradation is frequently a subject of laboratory and field evaluations.

Relevant tests

ASTM E2454 Standard Guide for Sensory Evaluation Methods to Determine the Sensory Shelf -life of Consumer Products

DoD 4140.27M Shelf Life Management Manual, 2000

ISO 11987 Ophthalmic Optics, Contact Lenses, Determination of Shelf Life

Barrier Properties

Many products degrade with exposure to the atmosphere: foods, pharmaceuticals, chemicals, etc. The ability of a package to control the permeation and penetration of gasses is vital for many types of products. Tests are often conducted on the packaging materials but also on the completed packages, sometimes after being subjected to flexing, handling, vibration, or temperature.

Degradation of Packages

Packages can degrade with exposure to temperature, humidity, time, sterlization (steam, radiation, gas, etc.), sunlight, and other environmental factors. For some types of packaging, it is common to test for possible corrosion of metals, polymer degradation, and weather testing of polymers. Several types of accelerated aging of packaging and materials can be accomplished in a laboratory.

Exposure to elevated temperatures accelerates some degradation mechanisms. An Arrhenius equation is often used to correlate certain chemical reactions at different temperatures, based on the proper choice of Q₁₀ coefficients.

As with any laboratory testing, validating field trials are important.

Relevant tests

ASTM D3045 Standard Practice for Heat Aging of Plastics without Load

ASTM F1640 Standard Guide for Packaging Materials for Foods to be Irradiated

ASTM F1980– Standard Guide for Accelerated Aging of Sterile Medical Device Packages

ASTM G151 Standard Practice for Exposing Non-metallic Materials in Accelerated Test Devices that are Laboratory Light Sources

Vacuum testing

Vacuum chamber for testing leaks in packaging component

Vacuum chambers are used to test the ability of a package to withstand low pressures. This can be to:

Determine the ability of packages to withstand low pressures that might be encountered. this could be in an air shipment or high altitude truck shipment.^[12]

A laboratory vacuum places controlled stress on a sealed package to test the strength of seals, the tendency for leakage, and the ability to retain sterility.

Relevant tests

ASTM D3078- Standard Test Method for Determination of Leaks in Flexible Packaging by Bubble Emission

ASTM D4991- Standard Test Method for Leakage Testing of Empty Rigid Containers by Vacuum Method

ASTM D6653- Standard Test Methods for Determining the Effects of High Altitude on Packaging Systems by Vacuum Method

ASTM D6834- Standard Test Method for Determining Product Leakage from a Package with a Mechanical Pump Dispenser

ASTM E493- Standard Test Methods for Leaks Using the Mass Spectrometer Leak Detector in the Inside-Out Testing Mode

ASTM F2338- Standard Test Method for Nondestructive Detection of Leaks in Packages by Vacuum Decay Method

ASTM F2391- Standard Test Method for Measuring Package and Seal Integrity Using Helium as the Tracer Gas

Shock and impact

Instrumented drop test of cushioned package to measure the transmitted shock

Both primary (consumer) packages and shipping containers have a risk of being dropped or being impacted by other items. Package integrity and product protection are important packaging functions. Tests are conducted to measure the resistance of packages and products to controlled laboratory shock and impact.

Testing also determines the effectiveness of package cushioning to isolate fragile products from shock. Instrumentation is used to measure the shock transmitted to a cushioned product.

Relevant tests

ASTM D880- Standard Test Method for Impact Testing for Shipping Containers and Systems

ASTM D1596- Standard Test Method for Dynamic Shock Cushioning Characteristics of Packaging Materials

ASTM D3332- Standard Test Methods for Mechanical-Shock Fragility of Products, Using Shock Machines

ASTM D4003- Standard Test Methods for Programmable Horizontal Impact Test for Shipping Containers and Systems

ASTM D5265- Standard Test Method for Bridge Impact Testing

ASTM D5276- Standard Test Method for Drop Test of Loaded Containers by Free Fall

ASTM D5277- Standard Test Method for Performing Programmed Horizontal Impacts Using an Inclined Impact Tester

ASTM D5487- Standard Test Method for Simulated Drop of Loaded Containers by Shock Machines

ASTM D6344- Standard Test Method for Concentrated Impacts to Transport Packages

ASTM D6537- Standard Practice for Instrumented Package Shock Testing For Determination of Package Performance

Package Insulation

Many packages are used for products that are sensitive to temperature. The ability of insulated shipping containers to protect their contents from exposure to temperature fluctuations can be measured in a laboratory. The testing can be of empty containers or of full containers with appropriate jell or ice packs, contents, etc. Ovens, freezers, and environmental chambers are commonly used for this and other types of packaging.

Digital temperature data loggers are used to measure temperatures experienced in different distribution systems. This data is sometimes used to develop unique laboratory test methods for that distribution system.

Relevant tests

ASTM D3103-Standard Test Method for Thermal Insulation Performance of Distribution Packages

ISTA 7E – Testing Standard for Thermal Transport Packaging Used in Parcel Delivery System Shipment

Thermal shock

Some packages, particularly glass, can be sensitive to sudden changes in temperature: Thermal shock. One method of testing involves rapid movement from cold to hot water baths, and back.

Relevant tests

ASTM C149 -Standard Test Method for Thermal Shock Resistance of Glass Containers

MIL-STD-810G METHOD 503.5

Handles

Package handles (and hand holes in packages) assist carrying and handling packages. Objective laboratory procedures are frequently used to help determine performance. Fixtured ‘’hands’’ of various designs are used to hold a handle (sometimes two handles for a box). Most common are “jerk testing’’ by modified drop test procedures or use of the constant pull rates of a universal testing machine. Other procedures use a static force by hanging a heavily loaded package for an extended time or even using a centrifuge.

Relevant tests

ASTM D6804, Standard Guide for Hand Hole Design in Corrugated Boxes, Appendix

Vibration

Vibration tester to simulate vibration frequencies at which packaged products are subjected during shipments

Vibration is encountered during shipping (vehicle vibration, rough roads, etc.) and movement on conveyors. Potential vibration damage may include:

fractures and fatigue damage

loose wires, screw caps, etc.

bruises on soft products (fruit, etc.)

surface abrasion

etc.

The ability of a package to withstand these vibrations and to protect the contents can be measured by several laboratory test procedures. Some allow searching for the particular frequencies of vibration that have potential for damage. Modal testing methodologies are sometimes employed. Others use specified bands of random vibration to better represent complex vibrations measured in field studies of distribution environments.

Relevant tests

ASTM D999- Standard Test Methods for Vibration Testing of Shipping Containers

ASTM D3580-Standard Test Methods for Vibration (Vertical Linear Motion) Test of Products

ASTM D4728- Standard Test Method for Random Vibration Testing of Shipping Containers

ASTM D5112- Standard Test Method for Vibration (Horizontal Linear Sinusoidal Motion) Test of Products

ASTM D7387- Standard Test Method for Vibration Testing of Intermediate Bulk Containers (IBCs) Used for Shipping Liquid Hazardous Materials (Dangerous Goods)

Compression

Compression test for steel drum

Compression testing relates to stacking or crushing of packages, particularly shipping containers. It usually measures of the force required to crush a package, stack of packages, or a unit load. Packages can be empty or filled as for shipment. A force-deflection curve used to obtain the peak load or other desired points. Other tests use a constant load and measure the time to failure or to a critical deflection.

Dynamic compression is sometimes tested by shock or impact testing with an additional load to crush the test package. Dynamic compression also takes place in stacked vibration testing.

Relevant Tests

ASTM Standard D642 Test Method for Determining Compressive Resistance of Shipping Containers, Components, and Unit Loads.

ASTM Standard D4577 Test Method for Compression Resistance of a Container Under Constant Load

ASTM Standard D7030 Test Method for Short Term Creep Performance of Corrugated Fiberboard Containers Under Constant Load Using a Compression Test Machine

German Standard DIN 55440-1 Packaging Test; compression test; test with a constant conveyance-speed

ISO 12048 Packaging—Complete, filled transport packages—Compression and stacking tests using a compression tester

Large loads

Rotational corner drop test of wooden box

Large pallet loads, bulk boxes, wooden boxes, and crates can be evaluated by many of the other test procedures previously listed. In addition, some special test methods are available for these larger loads.

Relevant tests

ASTM D5331- Standard Test Method for Evaluation of Mechanical Handling of Unitized Loads Secured with Stretch Wrap Films

ASTM D5414- Standard Test Method for Evaluation of Horizontal Impact Performance of Load Unitizing Stretch Wrap Films

ASTM D5415- Standard Test Method for Evaluating Load Containment Performance of Stretch Wrap Films by Vibration Testing

ASTM D5416- Standard Test Method for Evaluating Abrasion Resistance of Stretch Wrap Films by Vibration Testing

ASTM D6055- Standard Test Methods for Mechanical Handling of Unitized Loads and Large Shipping Cases and Crates

ASTM D6179- Standard Test Methods for Rough Handling of Unitized Loads and Large Shipping Cases and Crates

ISO 10531- Stability testing of unit loads

Test Protocols for Shipping Containers

Shipping containers are often subjected to sequential tests involving a combination of individual test methods. A variety of standard test schedules or protocols are available for evaluating transport packaging. They are used to help determine the ability of complete and filled shipping containers to various types of logistics systems. Some test the general ruggedness of the shipping container while others have been shown to reproduce the types of damage encountered in distribution. Some base the type and severity of testing on formal studies of the distribution environment: instrumentation, data loggers, and observation. Test cycles with these documented elements better simulate parts of certain logistics shipping environments.

ASTM International

ASTM D4169- Standard Practice for Performance Testing of Shipping Containers and Systems

ASTM D7386- Standard Practice for Performance Testing of Packages for Single Parcel Delivery Systems.

ISO

ISO 4180:2009 Packaging – Complete filled transport packages – General rules for the compilation of performance test schedules

International Safe Transit Association

Procedure 1A: Packaged-Products weighing 150 lb (68 kg) or Less

Procedure 1B: Packaged-Products weighing Over 150 lb (68 kg)

Procedure 1C: Extended Testing for Individual Packaged-Products weighing 150 lb (68 kg) or Less

Procedure 1D: Extended Testing for Individual Packaged-Products weighing Over 150 lb (68 kg)

Procedure 1E: Unitized Loads

Procedure 1G: Packaged-Products weighing 150 lb (68 kg) or Less (Random Vibration)

Procedure 1H: Packaged-Products weighing Over 150 lb (68 kg) (Random Vibration)

Procedure 2A: Packaged-Products weighing 150 lb (68 kg) or Less

Procedure 2B: Packaged-Products weighing over 150 lb (68 kg)

Procedure 2C: Furniture Packages

Procedure 3A: Packaged-Products for Parcel Delivery System Shipments 70 kg (150 lb) or Less (standard, small, flat or elongated)

Procedure 3B: Packaged-Products for Less-Than-Truckload (LTL) Shipment

Procedure 3E: Unitized Loads of Same Product

Procedure 3F: Packaged Products for Distribution Center to Retail Outlet Shipment 100 lb (45 kg)

Procedure 3H: Performance Test for Products or Packaged-Products in Mechanically Handled Bulk Transport Containers

Project 3K: Fast Moving Consumer Goods for the European Retail Supply Chain

Project 4AB: Enhanced Simulation Performance Tests (online test planner)

6-FEDEX-A: FedEx Procedures for Testing Packaged Products Weighing Up to 150 lbs

6-FEDEX-B: FedEx Procedures for Testing Packaged Products Weighing Over 150 lbs

6-SAMSCLUB, Packaged-Products for Sam’s Club® Distribution System Shipment

Procedure 7D: Thermal Controlled Transport Packaging for Parcel Delivery System Shipment

ISTA 7E: Testing Standard for Thermal Transport Packaging Used in Parcel Delivery System

Field trials

Laboratory testing can often help identify shipping container constructions that, in general, should perform well in the field. Of course, laboratory tests cannot fully reproduce the full range of field hazards, their magnitudes, nor their frequency. Field experiments are often conducted to help validate the laboratory testing.

The advantage of laboratory testing is that it subjects replicate packages to identical sets of test sequences: a relatively small number of samples often can suffice. Field hazards, by their nature, are highly variable: thus repeated shipments do not receive the same types or magnitudes of drops, vibrations, kicks, impacts, abrasion, etc. Because of this uncontrolled variability, more replicate sample shipments are often necessary.

Larger scale test markets are used to give additional assurance of performance and acceptability for a new or revised packaged-product. Feedback is carefully obtained and evaluated. Feedback on package performance continues when full production and distribution have been achieved.

Product requirements

In addition, package testing often relates to the specific product inside the package. Some broad categories of products and special package testing considerations follow:

Food packaging

Foods categories such as fresh produce, frozen foods, irradiated foods, fresh fish, canned foods, etc. have regulatory requirements and special packaging needs. Package testing often relates to:

Food safety

Compatibility of the package with the food

Migration of material from the packaging to the food

Shelf life

Barrier properties, porosity, package atmosphere, etc

Special quality assurance needs, good manufacturing practices, HACCP, validation protocols, etc

Pharmaceutical packaging

Packaging for drugs and pharmaceuticals is highly regulated. Special testing needs include:

Safety of drugs and pharmaceuticals

Barrier properties

Shelf life

Compatibility of package with the drugs

Sterility

Tamper resistance, child resistance, etc

Special quality assurance needs, good manufacturing practices, validation protocols, etc

Medical Packaging

Packaging for medical materials, medical devices, health care supplies, etc., have special user requirements and is highly regulated. Barrier properties, durability, visibility, sterility and strength need to be controlled; usually with documented test results for initial designs and for production.

Assurance of sterility and suitability for use are critical. For example, medical devices and products are often sterilized in the package. The sterility must be maintained throughout distribution to allow immediate use by physicians. A series of special packaging tests is used to measure the ability of the package to maintain sterility. Verification and validation protocols are rigidly maintained.

Relevant standards

ASTM F1585 – Guide for Integrity Testing of Porous Medical Packages

ASTM D3078 – Standard Test Method for Detection of Leaks in Flexible Packaging (Bubble)

ASTM F1140 – Standard Test Methods for Internal Pressurization Failure Resistance of Unrestrained Packages

ASTM F1608 – Standard Test Method for Microbial Ranking of Packaging Materials

ASTM F1929 – Standard Test Method for Detecting Seal Strength in Porous Medical Packaging by Dye Penetration

ASTM F2054 – Standard Test Method for Burst Testing of Flexible Package Seals Using Internal Air Pressurization Within Restraining Plates

ASTM F2095 – Standard Test Methods for Pressure Decay Leak Test for Flexible Packages With and Without Restraining Plates

ASTM F2096 – Standard Test Method for Detecting Gross Leaks in Medical Packaging by Internal Pressurization

ASTM F2097 – Standard Guide for Design and Evaluation of Primary Flexible Packaging for Medical Products

ASTM F2228 – Standard Test Method for Non-Destructive Detection of Leaks in Medical Packaging Which Incorporates Pourous Barrier Material by CO2 Tracer Gas

ASTM F2391 – Standard Test Method for Measuring Package and Seal Integrity using Helium as the Tracer Gas

ASTM F3039 - Standard Test Method for Detecting Leaks in Nonporous Packaging or Flexible Barrier Materials by Dye Penetration

EN 868-1 – Packaging materials and systems for medical devices which are to be sterilized. General requirements and test methods (superseded by ISO 11607-1)

ISO 11607-1 – Packaging for terminally sterilized medical devices -- Part 1: Requirements for materials, sterile barrier systems and packaging systems

ISO 11607-2 – Packaging for terminally sterilized medical devices -- Part 2: Validation for Forming, Sealing, and Assembly Processes

Dangerous Goods

Packaging of hazardous materials, or dangerous goods, are highly regulated. There are some material and construction requirements but also performance testing is required. The testing is based on the packing group (hazard level) of the contents, the quantity of material, and the type of container.^[13]

Relevant standards

ASTM D4919- Standard Specification for Testing of Hazardous Materials Packaging

ASTM D7387- Standard Test Method for Vibration Testing of Intermediate Bulk Containers (IBCs) Used for Shipping Liquid Hazardous Materials (Dangerous Goods)

ASTM D7760 Standard Guide for Conducting Internal Pressure Tests on United Nations (UN) Packagings

ASTM D7887 Standard Guide for Selection of Substitute, Non-hazardous, Liquid Filling Substances for Packagings Subjected to the United Nations Performance Tests

ASTM D7790: Standard Guide for Preparation of Plastic Packagings Containing Liquids for United Nations (UN) Drop Testing

UN Recommendations on the Transport of Dangerous Goods

ISO 16104 – 2003 Packaging – Transport packaging for dangerous goods – Test methods

References

^ Urbanek, T; Lee, Johnson. "Column Compression Strength of Tubular Packaging Forms Made of Paper" (PDF). 34, 6. Journal of Testing and Evaluation: 31–40. Retrieved 12 December 2011.mw-parser-output cite.citationfont-style:inherit.mw-parser-output .citation qquotes:"""""""'""'".mw-parser-output .citation .cs1-lock-free abackground:url("//upload.wikimedia.org/wikipedia/commons/thumb/6/65/Lock-green.svg/9px-Lock-green.svg.png")no-repeat;background-position:right .1em center.mw-parser-output .citation .cs1-lock-limited a,.mw-parser-output .citation .cs1-lock-registration abackground:url("//upload.wikimedia.org/wikipedia/commons/thumb/d/d6/Lock-gray-alt-2.svg/9px-Lock-gray-alt-2.svg.png")no-repeat;background-position:right .1em center.mw-parser-output .citation .cs1-lock-subscription abackground:url("//upload.wikimedia.org/wikipedia/commons/thumb/a/aa/Lock-red-alt-2.svg/9px-Lock-red-alt-2.svg.png")no-repeat;background-position:right .1em center.mw-parser-output .cs1-subscription,.mw-parser-output .cs1-registrationcolor:#555.mw-parser-output .cs1-subscription span,.mw-parser-output .cs1-registration spanborder-bottom:1px dotted;cursor:help.mw-parser-output .cs1-ws-icon abackground:url("//upload.wikimedia.org/wikipedia/commons/thumb/4/4c/Wikisource-logo.svg/12px-Wikisource-logo.svg.png")no-repeat;background-position:right .1em center.mw-parser-output code.cs1-codecolor:inherit;background:inherit;border:inherit;padding:inherit.mw-parser-output .cs1-hidden-errordisplay:none;font-size:100%.mw-parser-output .cs1-visible-errorfont-size:100%.mw-parser-output .cs1-maintdisplay:none;color:#33aa33;margin-left:0.3em.mw-parser-output .cs1-subscription,.mw-parser-output .cs1-registration,.mw-parser-output .cs1-formatfont-size:95%.mw-parser-output .cs1-kern-left,.mw-parser-output .cs1-kern-wl-leftpadding-left:0.2em.mw-parser-output .cs1-kern-right,.mw-parser-output .cs1-kern-wl-rightpadding-right:0.2em

^ ASTM D6954 Standard Guide for Exposing and Testing Plastics that Degrade in the Environment by a Combination of Oxidation and Biodegradation

^ Cooke, Linda (March 1998). "Pest-Proofing Food Packaging" (PDF). Agricultural Research

^ Kiyohide, Hasegawa (2004). "Recent Trend of Transport Packaging Test". JPI Journal. 42 (9): 716–722. Retrieved 16 Feb 2010.

^ Dvorak, Paul (June 1, 2008). "Package Testing as Risk Management". Retrieved 2010-02-16.

^ Johnson, C (1995). "In-House Testing of Computer Packaging". In Fiedler, R M (ed.). Distribution Packaging Technology. IoPP

^ Maloney, J. C. (July 2003). "The History and Significance of Military Packaging" (PDF). Defence Packaging Policy Group. Defence Logistics Agency. Retrieved 7 June 2011.

^ "CPSC Requirements under the Poison Prevention Packaging Act" (PDF). CPSC.

^ ASTM D7298

^ Bix, L; Kosugi; Wartaru; Sundar; Becker (2010). "The use of change detection as a method of objectively evaluating labels". Packaging Technology and Science. 23 (7): 393–401. doi:10.1002/pts.904.

^ Marcondes, Jorge; Hatton; Graham; Schueueman (July 2003). "Effect of temperature on the cushioning properties of some foamed plastic materials". Packaging Technology and Science. 16 (2): 69–76. doi:10.1002/pts.614.

^ Singh, P., Burgess, G., Kremer, M. and Lockhart, H. Effect of Reduced Pressure, Vibration and Orientation to Simulate High Altitude Testing of Liquid Pharmaceutical Glass and Plastic Bottles. Packaging Technology and Science, vol. 20. 2007.

^ "How to Comply with Federal Hazardous Materials Regulations". US DoT.

Books, General References

ASTM STP 1294 Durability Testing of Nonmetallic Materials, 1996

Lockhart, H., and Paine, F.A., "Packaging of Pharmaceuticals and Healthcare Products", 2006, Blackie,
ISBN 0-7514-0167-6

Meisner, "Transport Packaging", Third Edition, IoPP, 2016

Pilchik, R., "Validating Medical Packaging" 2002,
ISBN 1-56676-807-1

Robertson, G. L., "Food Packaging", 2005,
ISBN 0-8493-3775-5

Russel, P G, and Daum, M P, "Product Protection Test Book", IoPP

Soroka, W, "Fundamentals of Packaging Technology", IoPP, 2002,
ISBN 1-930268-25-4

Yam, K. L., "Encyclopedia of Packaging Technology", John Wiley & Sons, 2009,
ISBN 978-0-470-08704-6

Guidelines for Selecting and Using ISTA Procedures and Projects, ISTA, 2013

External links

Institute of Packaging Professionals

International Safe Transit Association (ISTA)

American Society for Testing and Materials

Safe Load Testing Technologies, 'All you need to know about Amazon ISTA Test', 2018

[1] Urbanek, T; Lee, Johnson. "Column Compression Strength of Tubular Packaging Forms Made of Paper" (PDF). 34, 6. Journal of Testing and Evaluation: 31–40. Retrieved 12 December 2011.mw-parser-output cite.citationfont-style:inherit.mw-parser-output .citation qquotes:"""""""'""'".mw-parser-output .citation .cs1-lock-free abackground:url("//upload.wikimedia.org/wikipedia/commons/thumb/6/65/Lock-green.svg/9px-Lock-green.svg.png")no-repeat;background-position:right .1em center.mw-parser-output .citation .cs1-lock-limited a,.mw-parser-output .citation .cs1-lock-registration abackground:url("//upload.wikimedia.org/wikipedia/commons/thumb/d/d6/Lock-gray-alt-2.svg/9px-Lock-gray-alt-2.svg.png")no-repeat;background-position:right .1em center.mw-parser-output .citation .cs1-lock-subscription abackground:url("//upload.wikimedia.org/wikipedia/commons/thumb/a/aa/Lock-red-alt-2.svg/9px-Lock-red-alt-2.svg.png")no-repeat;background-position:right .1em center.mw-parser-output .cs1-subscription,.mw-parser-output .cs1-registrationcolor:#555.mw-parser-output .cs1-subscription span,.mw-parser-output .cs1-registration spanborder-bottom:1px dotted;cursor:help.mw-parser-output .cs1-ws-icon abackground:url("//upload.wikimedia.org/wikipedia/commons/thumb/4/4c/Wikisource-logo.svg/12px-Wikisource-logo.svg.png")no-repeat;background-position:right .1em center.mw-parser-output code.cs1-codecolor:inherit;background:inherit;border:inherit;padding:inherit.mw-parser-output .cs1-hidden-errordisplay:none;font-size:100%.mw-parser-output .cs1-visible-errorfont-size:100%.mw-parser-output .cs1-maintdisplay:none;color:#33aa33;margin-left:0.3em.mw-parser-output .cs1-subscription,.mw-parser-output .cs1-registration,.mw-parser-output .cs1-formatfont-size:95%.mw-parser-output .cs1-kern-left,.mw-parser-output .cs1-kern-wl-leftpadding-left:0.2em.mw-parser-output .cs1-kern-right,.mw-parser-output .cs1-kern-wl-rightpadding-right:0.2em

[2] ASTM D6954 Standard Guide for Exposing and Testing Plastics that Degrade in the Environment by a Combination of Oxidation and Biodegradation

[3] Cooke, Linda (March 1998). "Pest-Proofing Food Packaging" (PDF). Agricultural Research

[4] Kiyohide, Hasegawa (2004). "Recent Trend of Transport Packaging Test". JPI Journal. 42 (9): 716–722. Retrieved 16 Feb 2010.

[5] Dvorak, Paul (June 1, 2008). "Package Testing as Risk Management". Retrieved 2010-02-16.

[6] Johnson, C (1995). "In-House Testing of Computer Packaging". In Fiedler, R M (ed.). Distribution Packaging Technology. IoPP

[7] Maloney, J. C. (July 2003). "The History and Significance of Military Packaging" (PDF). Defence Packaging Policy Group. Defence Logistics Agency. Retrieved 7 June 2011.

[8] "CPSC Requirements under the Poison Prevention Packaging Act" (PDF). CPSC.

[9] ASTM D7298

[10] Bix, L; Kosugi; Wartaru; Sundar; Becker (2010). "The use of change detection as a method of objectively evaluating labels". Packaging Technology and Science. 23 (7): 393–401. doi:10.1002/pts.904.

[11] Marcondes, Jorge; Hatton; Graham; Schueueman (July 2003). "Effect of temperature on the cushioning properties of some foamed plastic materials". Packaging Technology and Science. 16 (2): 69–76. doi:10.1002/pts.614.

[12] Singh, P., Burgess, G., Kremer, M. and Lockhart, H. Effect of Reduced Pressure, Vibration and Orientation to Simulate High Altitude Testing of Liquid Pharmaceutical Glass and Plastic Bottles. Packaging Technology and Science, vol. 20. 2007.

[13] "How to Comply with Federal Hazardous Materials Regulations". US DoT.

v t e Packaging
General topics	Active packaging Child-resistant packaging Contract packager Modified atmosphere/modified humidity packaging Package pilferage Package testing Packaging engineering Reusable packaging Shelf life Shelf-ready packaging Shelf-stable Sustainable packaging Tamper-evident Tamper resistance Wrap rage
Product packages	Alternative wine closure Beer bottle Box wine Case-ready meat Cosmetic packaging Currency packaging Disposable food packaging Drink can Egg carton Evidence packaging Foam food container Food packaging Glass milk bottle Growler Juicebox Luxury packaging Milk bag Optical disc packaging Popcorn bag Pharmaceutical packaging Plastic milk container Self-heating food packaging Screw cap (wine) Water bottle Wine bottle
Containers	Aerosol spray Aluminium bottle Aluminum can Ampoule Antistatic bag Bag-in-box Bag Barrel Biodegradable bag Blister pack Boil-in-bag Bottle Box Bulk box Cage Case Carboy Carton Chub Clamshell Corrugated box design Crate Disposable cup Drum Endcap Envelope Flexible intermediate bulk container Folding carton Glass bottle Inhaler Insulated shipping container Intermediate bulk container Jar Jerrycan Jug Keg Mesh bag Multi-pack Oyster pail Packet (container) Padded envelope Pail Paper bag Paper sack Plastic bag Plastic bottle Retort pouch Sachet Security bag Self-heating can Shipping container Skin pack Spray bottle Tetra Brik Tin can Thermal bag Tub (container) Tube Unit load Vial Wooden box
Materials and components	Adhesive Aluminium foil Bail handle Bioplastic Biodegradable plastic BoPET Bubble wrap Bung Cellophane Closure Coated paper Coating Coextrusion Corrugated fiberboard Corrugated plastic Cushioning Desiccant Double seam Foam peanut Gel pack Glass Hot-melt adhesive Kraft paper Label Lid Linear low-density polyethylene Liquid packaging board Low-density polyethylene Metallised film Modified atmosphere Molded pulp Nonwoven fabric Overwrap Oxygen scavenger Package handle Packaging gas Pallet Paper Paper pallet Paperboard Plastic film Plastic pallet Plastic wrap Polyester Polyethylene Polypropylene Pressure-sensitive tape Pump dispenser Screw cap Screw cap (wine) Security printing Security tape Shock detector Shock and vibration data logger Shrink wrap Slip sheet Staple (fastener) Strapping Stretch wrap Susceptor Tamper-evident band Tear tape Temperature data logger Time temperature indicator Tinplate Velostat
Processes	Aseptic processing Authentication Automatic identification and data capture Blow fill seal Blow molding Calendering Canning Coating Containerization Corona treatment Curtain coating Die cutting Die forming (plastics) Electronic article surveillance Extrusion Extrusion coating Flame treatment Glass production Graphic design HACCP Hermetic seal Induction sealing Injection moulding Lamination Laser cutting Molding Package tracking Papermaking Plastic welding Plastics extrusion Printing Quality assurance Radio-frequency identification Roll slitting Shearing (manufacturing) Thermoforming Track and trace Vacuum forming Ultrasonic welding Vacuum packaging Verification and validation
Machinery	Barcode printer Barcode reader Bottling line Calender Can seamer Cartoning machine Case sealer Check weigher Conveyor system Extended core stretch wrapper Filler Heat gun Heat sealer Industrial robot Injection molding machine Label printer applicator Lineshaft roller conveyor Logistics automation Material-handling equipment Mechanical brake stretch wrapper Multihead weigher Orbital stretch wrapper Packaging machinery Palletizer Rotary wheel blow molding systems Shrink tunnel Staple gun Tape dispenser Turntable stretch wrapper Vertical form fill sealing machine
Environment, post-use	Biodegradation Environmental engineering Glass recycling Industrial ecology Life-cycle assessment Litter Packaging waste Paper recycling Plastic recycling Recycling Reusable packaging Reverse logistics Source reduction Sustainable packaging Waste management
• Category: Packaging

v t e Product testing
Testing organizations	Standards organization Consumer organization Trade organization Food safety organization
Methodologies	Conformance testing Chemical test Destructive testing Discrimination testing Nondestructive testing Physical test Sensory analysis Survey research Test method Usability testing
Product fields	Cannabis testing Coffee cupping Crash test Clinical trial Package testing Software testing Whisky tasting Wine tasting

Contents

Purposes

Importance of testing

Laboratory affiliation

Procedures

Materials testing

Testing with people

Relevant standards

Conditioning, testing atmosphere

Relevant Standards

Degradation of product

Relevant tests

Barrier Properties

Degradation of Packages

Relevant tests

Vacuum testing

Relevant tests

Shock and impact

Relevant tests

Package Insulation

Relevant tests

Thermal shock

Relevant tests

Handles

Relevant tests

Vibration

Relevant tests

Compression

Relevant Tests

Large loads

Relevant tests

Test Protocols for Shipping Containers

Field trials

Product requirements

Food packaging

Pharmaceutical packaging

Medical Packaging

Dangerous Goods

See also

References

Books, General References

External links

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