GORE^® Universal Pipe Gasket (Style 800)

GORE Universal Pipe Gasket (Style 800) is available in ring or full-face styles, manufactured to ASME, EN or JIS standards.

For other sizes or custom gaskets, contact Gore.

Test Method

The ASTM F36 test method covers determination of the short-time compressibility and recovery at room temperature of sheet-gasket materials. It is not intended as a test for compressibility under prolonged stress application, generally referred to as "creep."

Source: ASTM International. Standard Test Method for Compressibility and Recovery of Gasket Materials - Designation: F36–99 (Reapproved 2009)

Test Method

ASTM F38 provides a means of measuring the amount of creep relaxation of a gasket material at a predetermined time after a compressive stress has been applied. This test method is designed to compare related materials under controlled conditions and their ability to maintain a given compressive stress as a function of time.

Source: ASTM International. Standard Test Methods for Creep Relaxation of a Gasket Material - Designation: ASTM F38-00 (2014)

Test Method

ASTM F37 provides a means of evaluating the sealing properties of sheet and solid form-in-place gasket materials at room temperature. This test method is designed to compare gasket materials under controlled conditions and to provide a precise measure of leakage rate.

Source: ASTM International. Standard Test Methods for Sealability of Gasket Materials - Designation: ASTM F37-06 (2013)

Test Method

This test method is currently being proposed as a new ASTM test method by the Committee F03 on Gaskets. ARLA determines the long term (aged) relaxation, leakage, weight loss and adhesion performance of gasket materials for pressurized bolted flanged connections. A mechanical integrity check of the material is also done. The method applies mainly to circular gasket products typically used in process or power plant pressure vessels and piping.

Source: ASTM International. New Test Method for AGED RELAXATION LEAKAGE ADHESION PERFORMANCE of Gaskets - Designation: ASTM WK26065

General Test Procedure

1. Place the gasket in the ARLA fixture
2. Measure the distance between platens
3. Load the gasket to initial compressive stress
4. Measure the stud length
5. Measure the distance between platens
6. Measure the leak rate (using a Helium Mass Spectrometer) using helium gas at 800 psig
7. Age by placing the loaded fixture in a non-circulating air oven
8. Remove the fixture from the oven and cool to room temperature
9. Measure the stud length
10. Measure the distance between platens

» Get the Blowout Certificate

Test Method

"The aim of the VDI guideline is to analyze and organize the applicable seal connection conditions based on the technical standard. Furthermore to complete the conditions, including latest research results, and advise the user in selection, interpretation, design, and assembling of flange joints in particular consideration of the gaskets."(1) "The here described blowout safety test of seals in sealing systems with even flanges corresponds with the current state of test engineering [...] a seal itself cannot accomplish blowout safety. It always depends on the entire system of the flange joint."

General Test Procedure

1. Installation of seal with installation surface pressure in four steps (25 %, 50 %, 75 % and 100 % of bolt force through crosswise tightening). Installation surface pressure and seal thickness are to be indicated in the test record. The lift-off force, caused by the nominal pressure, referring to the middle seal diameter, shall additionally be considered in all testing steps.
2. Retightening to installation surface pressure after 5 minutes.
3. Flange heating to temperature with 2 K/min in recirculation furnace or using inside heated cartridges.
4. Maintenance of thermal storage temperature for minimum 48 hours.
5. Cooling down of the flange to ambient temperature.
6. Measurement of the remaining surface pressure.

Test Step 1

The blowout safety test is performed with nitrogen up to the 1.5-fold of the nominal pressure. Tests with higher pressures are allowed, if required. The internal pressure is to be increased stepwise, in steps of 5 bar to the above mentioned pressure. The holding period per pressure stage amounts to a minimum of 2 min.

As "blowout" is defined, if, within 5 s, a pressure decay of Δp ≥ 1 bar· (V0 = test room volume) is exceeded. The achieved internal pressure is to be indicated in the test record. If blowout did not occur until the maximum test pressure, the test is to be continued according to test step 2.

Test Step 2

The internal pressure is discharged and the surface pressure is reduced to 5 N/mm² with regard to lifting force caused by the internal pressure. Variations of the surface pressure are to be stated in the testing report."⁽²⁾

⁽¹⁾ Source: Verein Deutscher Ingenieure e. V.: VDI 2200: Tight flange connections - Selection, calculation, design and assembly of bolted flange connections, June 2007, page 4
⁽²⁾ Source: ibidem, page 64

Test Method

This test method is currently being proposed as a new ASTM test method by the Committee F03 on Gaskets. This test method provides a means to determine realistic temperature limits for polytetrafluoroethylene (PTFE) based sheet or sheet-like gaskets to assist in avoiding catastrophic failure or blowout. This test method focuses on flanged joints common in the chemical process industry for moderate temperature ASME B16.5 Class 150 and Class 300 services.

Source: ASTM International. New Test Method for Hot Blowout and Thermal Cycling Performance for Polytetrafluoroethylene (PTFE) Sheet or Sheet-Like Gaskets - Designation: ASTM WK26064

General Test Procedure (Draft 7)

1. A gasket is loaded in a Hot Blow Out Test Rig, which is comprised of NPS 3 Class 150 or Class 300 raised face flanges. Using a torque wrench and best installation practices, the specified compressive stress is applied to the gasket.
2. A waiting period for gasket creep and relaxation of 30 minutes is observed before the gasket is reloaded to the specified gasket stress.
3. Another 30 minutes waiting period is observed before the rig is pressurized with helium gas.
4. For HOBT without thermal cycles, once the pressure is applied, the temperature is increased up to 648.9 °C (1200 °F) maximum at a 16.1 °C (3 °F) per minute rate until blow-out or maximum temperature of the rig is reached.
5. For HOBT with thermal cycles, once the pressure is applied, the temperature is increased at 16.1 °C (3 °F) per minute rate. The fixture is then cooled to room temperature. This cycle is repeated two more times for a total of three thermal cycles per test.

The procedure consists of three tests:

Test 1: HOBT without thermal cycles.
Test 2: HOBT with 3 thermal cycles using temperature estimation from Test 1.
Test 3: HOBT with 3 thermal cycles using temperature estimation from Test 2.

Test Method

This test method is currently being proposed as a new recommended practice for Gasket Constants for Bolted Joint Design by the Committee F03 on Gaskets. This practice determines room temperature gasket tightness design constants for pressurized bolted flanged connections such as those designed in accordance with The ASME Boiler & Pressure Vessel Code. It applies mainly to all types of circular gasket products and facings typically used in process or power plant pressure vessels, heat exchangers and piping including solid metal, jacketed, spiral wound and sheet type gaskets. As an option, the maximum assembly stress for those gaskets is also determined by this procedure.

Source: ASTM International. New Recommended Practice for GASKET CONSTANTS FOR BOLTED JOINT DESIGN - Designation: ASTM WK10193

General Test Procedure for Soft Gaskets (Draft 9)

1. A gasket is placed in a hydraulic flat platen test rig.
2. A series of 3 loadings and unloading cycles is applied during which leak rate is measured at each stress level. Depending on the step, the system is pressurized to either 27.5 bar (399 psi) or 55 bar (798 psi) using helium gas. The holding time at each step is dependent on when a leak rate stabilizes, with a minimum hold time of 1 minute and a maximum hold time of 5 hours.
3. The data collected is grouped into two Parts, Part A and Part B, and analyzed to generate the test parameters. Part A represents the initial seating performance of a gasket during initial flange tightening. Data from Part A is used to determine G_b, "a", and T_pmax. Part B simulates actual operating conditions. Data from Part B is used to determine G_s and T_pmin.

General Test Procedure for CRUSH (Draft 9)

1. The gasket stress is restored to S1 level.
2. Loading cycles, with gradually increasing compression stresses, are applied on the gasket during which leak rate is measured at each stress level. The system is pressurized to 27.5 bar (399 psi) using helium gas. The holding time shall not exceed 15 minutes at each stress level.
3. The test is complete when the leak rate at a stress level exceeds the leak rate observed at S1 level or when the maximum load of the equipment is reached.
4. Maximum Allowable Stress is the maximum stress level where S1 leak rates were maintained.

Test Results

Please find below the test results by tape thickness.

• GORE® Universal Pipe Gasket (Style 800) in 1.5 mm (1/16")
• GORE® Universal Pipe Gasket (Style 800) in 3 mm (1/8")
• GORE® Universal Pipe Gasket (Style 800) in 6 mm (1/4")

Note: If the gasket thickness is not directly listed above, use the data from the next higher thickness.

Test Method

EN 13555 provides the test method for generating the gasket parameters used in EN 1591-1 calculations. 

Test Method

m & y are gasket constants used for flange design as specified in the ASME Boiler and Pressure Vessel Research Code Division 1 Section VIII Appendix 2. Leak Rates versus Y stresses and m factor for Gaskets is currently being proposed as a new test method in the ASTM F03 Working Group.

Gasket Constant Definitions

m, maintenance factor, is a factor that describes the amount of additional preload required to maintain the compressive load on a gasket after internal pressure is applied to a joint. 

y, seating stress, is the minimum compressive stress (psi) required to achieve an initial seal.

Test Method

There are no specific test standards for AD 2000 B 7 Gasket Parameters. However, an estimation is provided below. The 2015 edition of "AD 2000-Merkblatt B 7" refers to EN 13555 as a test standard⁽¹⁾ and uses table 9 from VDI 2200⁽²⁾ for the conversion method. Please note that VDI 2200 states that such a conversion is invalid due to the different measurement methods. "Only the method according to DIN EN 1591-1 and AD 2000 in conjunction with DIN EN 1591-1 and FE analysis can be used for providing stability, leak tightness and TA Luft proof."⁽³⁾

Gore supports the use of the AD 2000-Merkblatt B 7 and provides the necessary gasket parameters below.

There are the following relations⁽¹⁾:

k₀K_D ≙ Q_min · b_D
k₁ ≙ (Q_Smin / p) · b_D since m ≙ (Q_Smin / p)⁽⁴⁾
k₀K_Dϑ ≙ Q_Smax · b_D

If necessary for a specific application, Gore recommends to do individual conversions based on data from EN 13555.

The use of the general values given in table 1 of AD 2000-Merkblatt B 7⁽⁵⁾ is not broadly recommended. However they may be applicable depending on the given situation.

Please also note that the quoted standards of DIN 2690 to DIN 2692 were superseded by EN 1514-1 in 1997.

⁽¹⁾Arbeitsgemeinschaft Druckbehälter: AD 2000-Merkblatt B 7, Berechnung von Druckbehältern, Schrauben, Seite 4, 7.1.2.4, April 2015.
⁽²⁾Verein Deutscher Ingenieure e. V.: VDI 2200, Tight flange connections - Selection, calculation, design and assembly of bolted flange connections, page 36, table 9, June 2007.
⁽³⁾Verein Deutscher Ingenieure e. V.: VDI 2290, Emission Control - Sealing constants for flange connections, page 8, June 2012.
⁽⁴⁾Please note that factor m = Q_Smin / p was defined by DIN V 2505 which was superseded by EN 1591-1 where m is no longer used.
⁽⁵⁾Arbeitsgemeinschaft Druckbehälter: AD 2000-Merkblatt B 7, Berechnung von Druckbehältern, Schrauben, Seite 6, Tabelle 1, April 2015.

For the TA Luft¹ test, the seal is installed in a DN40/PN40 steel flange, usually with a gasket stress of 30 MPa. The flange is then exposed to a defined temperature for minimum 48 hours. After cool down, leakage rate is measured over a period of at least 24 hours. The test pressure is 1 bar helium.

The ultimate final leakage rate after a test duration of 24 hours must remain below 10^-4 mbar*l/(s*m) for the seal to qualify according to TA Luft.

TA Luft certificates are available for thicknesses 1.5 mm, 3 mm and 6 mm.

¹ Federal Ministry of Germany for the Environment, Nature Conservation, Building and Nuclear Safety: First General Administrative Regulation Pertaining the Federal Emission Control Act (Technical Instructions on Air Quality Control - TA Luft), Joint Ministerial Gazette, July 30, 2012.

The Federal Institute for Materials Research and Testing (BAM) tests the sealing material compatibility for use in flanged connections with liquid and gaseous oxygen. Further information on the test procedure and the result can be found in the following test report.

Eurochlor's publication on Experience of Gaskets in Liquid Chlorine and Dry or Wet Chlorine Gas Service and the Chlorine Institute's Pamphlet 95 Gaskets for Chlorine Service cover gaskets for both dry and wet chlorine service and highlight materials that have found user acceptance through field-testing and member company experience. GORE® GR Sheet Gasketing and GORE Universal Pipe Gasket (Style 800) are both listed in these publications. The documents are available from the respective organizations.

GORE Universal Pipe Gasket (Style 800) has received a Product Design Assessment (PDA) Certificate per the ABS Type Approval Program.

This test analyzes leachable water-soluble fluoride and chloride ions which can induce flange corrosion. The samples are leached for 24 hours at approximately 95 °C in demineralized water. Contact Gore for further information if this testing is required for your application.

GORE® Gasketing products meet the definition of an article; therefore, a Material Safety Data Sheet (MSDS) or Safety Data Sheet (SDS) is not required. However, for your convenience, a Product Safety Sheet, which details the intended use and proper handling of our articles, is provided.

The Gore Sealant Technologies Quality Management System is certified in accordance with ISO 9001.