Ignis Fire Testing - Articles , Articles

IGNIS FIRE TESTING URGES ENGINEERS TO VERIFY FIRE TEST REPORTS FOLLOWING CASES OF ALTERED DOCUMENTATION

Tue, 17 Mar 2026 13:38:00 +0200

Ignis Fire Testing has identified instances in which fire test reports issued by its laboratory have been altered after they were distributed to clients.

While these incidents appear limited, they raise significant concerns about the integrity of the documentation relied upon by engineers, regulators, and approval authorities in the built environment.

Fire test reports are technical records that document the performance and behaviour of construction materials and systems (or any other products) under controlled fire conditions. These reports are used to inform engineering decisions, demonstrate regulatory compliance, and guide fire safety design in buildings. Any modification to such documentation (including changes to performance ratings, scope of testing, drawings, or classification conditions) may misrepresent the actual performance or behaviour of materials or systems as tested.

As part of the report issuance process at Ignis Fire Testing, clients are required to acknowledge that reports may not be altered, edited, or modified and must only be distributed in their complete and original form. Once a report has been issued, however, we have no control over how that document is subsequently circulated.

Therefore, we encourage all industry stakeholders to obtain fire test reports directly from the laboratory – with the report owner’s consent – whenever documentation attributed to Ignis Fire Testing is used or relied upon, to ensure its accuracy. “Fire testing exists to provide objective, verifiable data that engineers can rely on when making critical safety decisions,” says civil engineer Dirk Streicher, owner of Ignis Fire Testing. “Guaranteeing that the reports being used are authentic and unaltered is imperative for maintaining confidence in the fire safety of the built environment. It could

save lives.”

Ignis Fire Testing maintains records of all official reports issued by its laboratory and can confirm the authenticity of any documentation attributed to us.

Our discovery of altered reports underscores the importance of strict document integrity throughout the construction and compliance chain. Sustaining confidence in fire performance data is critical to protecting buildings, infrastructure, products, and – most importantly – human lives.

For verification or confirmation of reports, engineers and industry professionals are invited to contact Ignis Fire Testing directly at

info@ignistesting.co.za or +27 (021) 905-0322 / +27 (021) 905-4814

IGNIS FIRE TESTING SERVES INSURERS WTIH ROBUST SPRINKLER TESTING

Fri, 21 Nov 2025 14:45:02 +0200

Insurers require reliable, independently verified data on fire-suppression systems to assess and manage risk and claims correctly. Recognising this, Ignis Fire Testing now offers specialised sprinkler head testing in accordance with the international standard ISO 6182-1 as well as sprinkler pipe testing. By providing efficient, high-volume verification of sprinkler system performance, we are a strategic partner for South African and global insurers, as well as building developers and owners.

Supporting insurers in underwriting and claims

For underwriters, accurate sprinkler performance data means better risk modelling, enhanced confidence in fire-suppression capability, and improved decision-making on policy terms and premiums. In claims situations, verified test results can support root‐cause investigations, knowledge of system integrity, and performance at the time of event.

With testing available locally in Cape Town, insurers and industry partners no longer face the delays and costs associated with shipping products overseas for testing.

Ignis Fire Testing’s rigorous sprinkler tests

We perform ISO 6182-1–compliant sprinkler testing that meets recognised international protocols, with rapid turnaround times and traceable, verifiable data suitable for underwriting and technical assessment.

We can test up to ten sprinkler heads simultaneously, which is mostly the number required to evaluate whether a sprinkler system is sufficiently functional. Tests can be conducted across the full range of temperature ratings (from 57 °C to 182 °C) applicable to different sprinkler heads, as required for various building types and risk classifications.

The test methodology uses either glycerine or water as the fluid medium in the testing bath. The bath’s temperature is controlled via a Proportional-Integral-Derivative (PID) controller in accordance with code requirements. The activation of each sprinkler head is captured.

We invite insurers to visit our facilities.

For more information or to schedule a sprinkler test demonstration, please contact us.

UNDERSTANDING LOAD-BEARING FIRE TESTS: ENSURING STRUCTURAL INTEGRITY AND SAFETY

Wed, 22 Jan 2025 10:04:07 +0200

A critical aspect of building safety is understanding how materials and structural elements perform in the event of a fire, especially when subject to loading. Load-bearing fire tests are essential evaluations that help ensure the load-bearing elements within a building – such as walls, floors, beams, and columns – can withstand fire while maintaining structural stability and integrity.

At Ignis Fire Testing, we specialise in conducting comprehensive load-bearing fire tests that contribute to safer, more resilient structures. According to our extensive research, no other facility on the continent performs these crucial tests.

Here is an in-depth look at what these tests involve, why they are necessary, and the benefits they provide.

What are Load-bearing Fire Tests?

Load-bearing fire tests evaluate how structural elements respond to fire when subject to the self-weight of the structure and imposed loads, also known as live loads. These tests go beyond standard fire resistance tests by simulating the structural capacity of elements at elevated temperatures, representing real-life scenarios in which walls, floors, or beams are exposed to fire while holding up parts of a building.

Prof Richards Walls from Stellenbosch University’s Fire Engineering Research Unit (FireSUN) explains, “During a fire, a loaded structural element distorts, meaning that building components can literally fall apart due to the combination of heat and force. Hence, testing walls and other systems under load helps us understand what would happen in a more realistic situation. Thus, loaded furnace tests give a more accurate assessment of a building’s components.”

During a load-bearing fire test, a test specimen, such as a wall or floor section, is constructed into a furnace (horizontal or vertical) and exposed to elevated temperatures, often reaching over 1000°C depending on the heating curve and test duration. Simultaneously, a load is applied, simulating load-bearing elements in practice, and the specimen is monitored to see how long it can resist the fire without collapsing or allowing fire spread. The results indicate whether the material can retain its structural strength and load-bearing capacity, providing vital insights into its performance during a fire.

Key Objectives of Load-Bearing Fire Tests?

The primary goal of load-bearing fire testing is to verify that structural elements can remain structurally sound under load when exposed to elevated temperatures, reducing the risk of collapse in an actual fire event. This test focuses on:

Stability: The test assesses whether a system or element can resist the loads it is subjected to under extreme heat without buckling, collapsing, or deflecting until exceeding limits.
Insulation: Load-bearing fire tests help determine whether the material can contain the fire by limiting heat transfer to other parts of the structure, reducing the spread of flames and providing additional time for evacuation.
Integrity: Another criterion is the ability of the system to contain the fire in a fire compartment – i.e., the system has no openings that spread flames on its unexposed surface.
Compliance and certification: Most building codes require materials and structures to meet fire safety standards. Load-bearing fire tests provide the necessary data for accreditation, ensuring that construction materials comply with these stringent safety standards.

Why Load-Bearing Fire Tests Are Essential

Fire can have a devastating effect on buildings, compromising structural elements that bear heavy loads. In such scenarios, the collapse of a load-bearing wall or floor could significantly impact safety, particularly if it occurs in multi-story structures. Load-bearing fire tests are a measure of understanding if structural elements can resist a fire under loaded conditions, giving occupants a critical window for evacuation and enabling firefighters to address the blaze safely.

By performing load-bearing fire tests, Ignis Fire Testing provides valuable technical information for engineers to make informed decisions about material selection, reinforcing a building's resilience to fire and improving occupant safety.

Ignis Fire Testing's Load-Bearing Tests

Ignis can perform static and pneumatic load-bearing fire tests in our vertical (3m x 3m) and horizontal (4m x 5m) furnaces.

We started by performing static load tests, such as vertical load-bearing tests on wall panels.

Subsequently, we changed to pneumatic applied loading – a method of applying force or pressure to a structure or material using compressed air rather than static weights. This approach enables more controlled, adjustable, and often higher force loads on the test structure, which is useful in simulating the different loads that might occur in real-life situations. The pressure can be increased or decreased as needed, providing flexibility to simulate different load conditions that may shift or intensify during a fire.

An example of pneumatic load-bearing tests that we performed includes testing of load-bearing flooring systems in our horizontal furnace.

However, this is not where it ends. We are in the process of building a new horizontal furnace to accommodate up to 5m x 4m decks and 5m load-bearing beam testing. This furnace can be adjusted to accommodate various sample sizes.

At Ignis Fire Testing, our commitment to safety is grounded in rigorous testing and high standards.

Our loadbearing fire tests provide several benefits:

Reliable data for informed safety decisions regarding materials and designs
Improved compliance with safety regulations
Reduced risk of catastrophic structural failure leading to loss of life and damage to property
Enhanced market confidence in tested materials

The Future Of Fire Safety Testing

As buildings grow taller and architectural designs become more complex, the importance of fire testing only increases. Ignis Fire Testing is dedicated to staying at the forefront of testing technology, adapting to evolving standards and helping to establish new benchmarks in fire safety. Our commitment to rigorous, accurate load-bearing fire testing ensures that we contribute to a safer future for everyone, especially on a continent where this type of testing is not prioritised.

THE EXPLOSIVE DANGERS OF LITHIUM-ION BATTERIES: INSIGHTS FROM IGNIS FIRE TESTING

Fri, 27 Sep 2024 09:04:19 +0200

Lithium-ion batteries, the powerhouse behind much of today’s technology – from smartphones to electric vehicles – carry significant fire hazards beyond mere flames. Unlike typical fires, lithium-ion battery fires do not merely flame and burn – they can explode with intense energy pressure waves, making them particularly dangerous. Dirk Streicher, founder and chief engineer at Ignis Fire Testing, offers the following insights.

Ignis Fire Testing is studying lithium ion batteries' reaction to fire.

What are the fire dangers of lithium-ion batteries?

Lithium-ion batteries do not burn like normal fires; they explode with high energy pressure waves. Initially, they spark severely and produce smoke and toxic gasses. The main problem is that they generate oxygen during burning, fueling the fire.

The burning process is the result of chemical reactions between the different layers or reactants in the cell. Due to the spontaneous emission of oxygen, heat radiation due to flaming, and the availability of highly reactant substances, the process will continue until the reactants are depleted.

What do manufacturers need to do to keep their batteries fire safe?

If this answer was known, there would not be a problem. In large lithium-ion manufacturing facilities or large storage warehouses, the one method is to flood the batteries with water. A good practice will always be to minimise the quantity of batteries stored in a contained unit.

What steps can the general public take to ensure the products they buy with lithium-ion batteries are safe?

The public should know that their products are not fire safe. It is perhaps more a question of how and where batteries are handled and stored. Charging inside a habitable space must not be allowed. The best and safest way to keep batteries will be outside a habitable space where there is enough ventilation to prevent capturing pressure waves.

Furthermore, do not try to extinguish a lithium-ion fire. By the time the fire is noted, it is too late. Run to a space where there are no smoke and toxic gasses and try to save nearby properties if fire spread is happening.

What kind of testing does Ignis provide for lithium-ion batteries?

The verdict is still out on the test methodology for lithium-ion batteries. The current tests we perform are to establish whether a handheld extinguisher filled with special content will extinguish a lithium-ion battery fire. When it comes to high-energy batteries, the testing becomes dangerous and should only be performed in specialised environments or away from nearby infrastructure.

For an in-depth explanation on accreditation of Ignis Testing read here.

DISSECTING CERTIFICATION AND TEST REPORTING

Wed, 19 Jul 2023 11:53:26 +0200

In order to understand the difference between certification and test reporting, it is helpful to understand the Quality Management system and the subtleties of the terms employed in quality procedures.

Quality Management oversees a set of systems that include Quality Assurance (QA), Quality Control, and Testing.

Testing provides data that feeds into the Quality Assurance (QA) process, and it forms an integral part of Quality Control measures.

Quality Control encompasses a set of activities, including testing, which are undertaken to ensure quality.

Quality Assurance (QA), in turn, results in the issuance of certification.

Therefore, testing is a subset of certification and plays a crucial role in the process leading to a product's certification.

Different quality management systems exist. For instance, ISO 9001 is a quality management system implemented to guarantee the consistent quality of a product. ISO 17025 is a quality management system applied in laboratories to ensure that the standard of testing and subsequent reporting is consistent and up to par. Ignis Testing abides by ISO 17025 standards and is managed by ECSA professional engineers w, implying professional liability to ensure correct and genuine reporting.

Unlike certification bodies, laboratories like Ignis Testing function as testing authorities, issuing test reports rather than certificates. These reports provide a detailed summary of measurements, results, and observations, all obtained in a controlled manner according to prescribed codes and standards. The accuracy and quality of these reports are greatly influenced by the professional conduct, integrity, and competence of our laboratory personnel.

At Ignis Testing, the test report is issued by a registered Professional Engineer. As such, the test report forms part of the supporting documentation submitted by the appointed competent fire engineer, in line with clause A19 of SANS 10400 Part A and form AZ4 in Annexure D of SANS 10400 Part A for certification.

A comprehensive quality management system must be in place for a manufacturer to issue a certificate. This system validates the test report, ensuring that the product, its components, materials, and manufacturing process align precisely with what was tested and detailed in the report.

The responsibility of ensuring the complete and accurate description of the tested product lies with the test laboratory. However, it is the manufacturer's responsibility to guarantee that the test report submitted to the engineer is valid for the delivered product.

For an in-depth explanation on accreditation of Ignis Testing read here.

IGNIS' INVOLVEMENT IN THE REVOLUTIONARY HEMP BUILDING PROJECT

Fri, 02 Jun 2023 14:17:20 +0200

Ignis is proud to have played a role in the groundbreaking hemp building project in Cape Town, South Africa. As a leading company in fire testing and safety, our contribution to this historic endeavour underscores our commitment to sustainable, eco-friendly construction and innovative technologies.

Recently the 12-storey hemp skyscraper at 84 Harrington Street in Cape Town marked a milestone in sustainable construction. Hempcrete blocks, made from cannabis plant cores, lime, and a chemical binder mix, offer a carbon-negative, environmentally friendly alternative to traditional building materials. In addition, these blocks provide excellent insulation, reducing the need for heating and air-conditioning, and are expected to become increasingly popular in construction worldwide over the next five years.

As a trusted partner in fire testing, Ignis evaluated the fire resistance of the hemp block assembly used in the Cape Town project. Our cutting-edge fire testing capabilities, based on SANS 10177 standards, allowed a thorough assessment of the hemp blocks' stability, integrity, and insulation.

Our fire testing process included the following:

A controlled furnace temperature and K-type thermocouples for accurate measurements
Photography to document the test as well as any possible smoke emission, flaming, and time of flaming
Monitoring surface temperatures and temperature attenuation through materials
Observing the stability, integrity, and insulation of tested materials
While not required of the standard, the distortion of the test element can be measured

As a result, the hemp block assembly was classified as having a 120-minute fire resistance in all three categories, which is the highest classification attainable under SANS 10177.

The successful completion of the Cape Town hemp skyscraper marks the beginning of a new era in sustainable construction. As hemp building materials gain popularity, Ignis is excited to continue our involvement in such projects, providing expert fire testing. Furthermore, we look forward to collaborating with other eco-friendly construction projects, further solidifying our commitment to sustainable practices and innovation in the industry. As we expand our services and expertise, Ignis remains dedicated to supporting groundbreaking, environmentally responsible projects like the Cape Town hemp skyscraper.

References

https://www.sapeople.com/2023/04/03/worlds-tallest-hemp-building-nearing-completion-in-cape-town-south-africa/

DIRECTION AND RELATED ISSUES FOR FIRE DOOR TESTING

Fri, 27 Jan 2023 16:02:14 +0200

(These notes are compiled by DJ Streicher (Pr.Eng.) of Ignis Testing Cape Town November 2020)

NARRATIVE

Decisions must be made during the design process regarding the testing of materials. It starts from identifying materials for the purpose, including the strength of materials and inter alia the properties of materials and specified building elements which will prevent and contain fire spread in buildings. Two design considerations are taken into account for fire spread design: protecting people and property. These considerations will include early warning systems, active fire suppression systems, and passive resistance of building elements of which fire-doors contribute a significant and critical proportion.

The problem starts to identify from which direction a fire will come. If an element is completely symmetrical, it is common sense that the direction of the material relative to the fire direction does not matter. However, if the element is non-symmetrical, it does not matter whether the element will have the same resistance against fire from either direction. It is thus clear that in this event, a non-symmetrical element must be tested bi-directionally to determine which direction is most demanding. If fire resistance tests of elements show no difference regarding direction, they can be designed the same way as an asymmetrical element. If it differs, then fire designs must take this phenomenon into account so that the highest resistance is in the direction of the fire. For example, single-sided hinged fire doors react differently bi-directionally. Why is this important? Because most divisional fire-door elements will consist of single-sided hinged doors.

FIRE TESTING CODES

Testing codes for doors usually consist of two primary codes. The first code guide the testing authority about equipment requirements, testing procedures, observations, and reporting. The second code will be a specific code against which parameters a door must be tested. SANS 10177-1 is a general administration code and SANS 10177-2 is the operational test code directing the testing authority on how to test. SANS 1253 is the fire doors and fire shutter code against which a door assembly will be tested. The equivalent European codes are EN 1363 parts 1 & 2 and the door code is EN 1634 parts 1 & 3. EN 1634-3 is for smoke control. The European codes are much more descriptive and address more parameters and test methodologies. There is no SABS smoke test control code for fire doors and shutters. When comparing codes, it is evident that the SABS and EN codes differ substantially. For instance, the EN code limits the frame temperature, which is not the case with the SABS code.

The time-temperature curve is a key parameter that is, fortunately, the same for all the fire resistance codes around the globe. It is this test input parameter that enables the comparison of doors from different manufacturers and countries. This so-called standard fire curve has been used for more than a hundred years and is the baseline reference for door test results in terms of resistance time. The outcome might be stricter for European results because additional items such as cotton pad tests, frame temperature requirements, radiation limits in kW/m², etc., could lead to higher standards. It must be noted that the insulation parameters are the same for the EN and SANS codes.

SANS 1253 FIRE DOOR AND SHUTTER CODE

Clause 3.7 of SANS 1253 defines a fire-door assembly as a door and its essential hardware so mounted on a frame that the required fire resistance is provided. Clause 3.6 describes a fire-door. It must be noted that a door is an assembly inclusive of the frame and hardware. A door leaf is a part that hangs on the frame or is alternatively described as the moving part. There is thus no doubt that a fire door test includes the entire combination of frame, fixing, frame type, door leaf and essential hardware to be built into the test furnace to resemble the final installation of the fire door.

Clause 4.2.1 clearly states A fire-door assembly shall be of fire resistance A, B, C, D, E, or F (see table 1), as required (see Annexure A). Clause 4.2.2 gives a list of types. We are only referring for this document to single- or double-leaf, hinged, single-action fire-door assemblies.

It is here where we have to define symmetry. Because the code refers to a fire-door assembly, symmetry applies to the assembly and NOT only to the leaf. For example, a single action hinged door fitted in a rebate is non-symmetrical for obvious reasons. The hinge pins are located on one side of the leaf, the rebate protects part of the leaf on one side and the door is not positioned in the centre of the frame.

Clause 5.4.1.2 states that if the construction (face to face) is non-symmetrical, test TWO samples to establish the fire resistance from both sides and take the lower results as the actual fire resistance. This clause overrides the direction clause in SANS 10177-2.

SANS 10177-2 FIRE RESISTANCE TEST FOR BUILDING ELEMENTS

Clause 3.5 of SANS 10177-2 defines Exposure in the furnace. Clause 3.5.1 addresses positioning.

3.5.1 b) in the case of a test specimen of an element that has the function of separating spaces, heat will be applied over the whole of one face only, the selection of that face being as follows:

1) If the elements are required to resist fire in one direction only, the heat will be applied in that direction;

2) if the element may be required to resist fire from either direction, the heat will be applied in the direction considered, by the testing authority, to give the lower resistance (in cases of doubt, each face should be tested on separate test specimens);

There is no doubt that clause 3.5.1 b) of SANS 10177-2 acknowledges the fact that there could be a difference in the fire resistance of an element depending on the direction of testing. Therefore, SANS 1253 is tested according to SANS 10177-2, which directs and controls the testing procedures and methodology.

Also, note that the onus is on the testing authority to direct the sponsor which test direction gives the lower resistance. At this point, it must be noted that if the sponsor instructs the testing authority to test a door in a direction giving lower resistance, then the testing authority will have to inform the sponsor. If a door is tested in the lower resistance direction, then according to 3.5.1 b) 1) it is accepted it is the direction in which the door will be installed. In the spirit of the code, it implies that doors cannot be classified with the same resistance in the other direction unless a door is tested in both directions.

DIRECTION OF FIRE DOOR TESTING

Regarding door testing, the direction of testing defines which direction the door opens relative to the furnace exposure. It is most commonly referred to as open inwards or opens outwards with reference to the exposed side. What is important to note is that the rebate is also on the exposed side in the case of an open inwards door.

Historic testing and test experience showed a difference between the fire resistance of a door opening inwards to the fire or a door opening outwards away from the fire. It is a known fact that an open inwards door is the more demanding direction of resistance. In short, it means the door assembly will fail quicker compared to an open outwards door. This phenomenon is well documented and accepted by testing authorities and international codes.

The EN 1634-1 code for fire doors has a specific clause, 13.4 Asymmetrical assemblies. This code acknowledges the principle for a difference between the direction of testing for doors. Table 2-Type of a door set and direction to be tested to cover the opposite direction covers the asymmetrical aspect. Only hinged doors with timber leaves opening inwards are covered in this table to include doors opening outwards w.r.t. resistance but not the other way round. A metal leaf in a metal frame can be regarded as symmetrical concerning the direction of testing. In conclusion to this table, it is only a timber leaf in a timber frame that can be classified as an open outwards door if tested open inwards. The rest all have insulation limitations. Note that no door with a timber leaf opening outwards will be regarded as passing a test opening inwards.

Annexure C (Informative) of the EN 1634-1 code explains the Background to the field of direct application statements for asymmetric constructions and supporting constructions.

REBATE SIZE

Rebate size is a moot point at many final building inspections. Clause 4.5.3.2 in SANS 1253 must be quoted. The width of the rebates of frames shall be at least 25 mm and the material thickness of steel frames should be at least 1.5 mm for class A, B, C, and D Doors. The first note to make is it does not apply to class E doors the way the clause is written.

None of the international fire door codes has such a restriction. Other codes do not specify dimensional parameters because a fire-door code is a performance specification, not a deemed to satisfy the specification. If a door assembly passes a test with a smaller rebate size, does this negate the test result? There is not enough evidence in all cases to prove that a larger rebate achieves higher fire resistance. There could even be cases where larger rebates are counterproductive.

FITTED HARDWARE

A phenomenon observed was locking doors with barrel bolts for testing purposes instead of fitting the locksets or hardware fitted on the production doors. We had test failures of well manufactured and designed doors because of incorrect lockset cut-outs. This type of failure would not be noticed if doors were fitted with bolts instead of the proper hardware. These tests failed before 20 minutes because of integrity failure at the lock. This failure emphasises the importance of testing a door assembly and not only on the door leaf.

REPORTING & TESTING FOR SOUTH AFRICAN MARKET

There is a clear misunderstanding and misinterpretation of the direction of fire door testing results in South Africa. The SANS fire testing codes are very clear that testing results must be comprehensive and complete. SANS 10177-2 clause 4.2.4 states that additional observations must also be made and recorded.

If one analyses SANS 10177-2 and SANS 1253, then the conclusion is that according to SANS 1253 clause 5.4.1.2, two samples of single-action hinged doors should be tested in two directions to determine the lower resistance. The code further states that the lower resistance must be given for a fire-door if tested according to SANS 1253. Thus, by implication, it means any classified fire- door can be fitted in any direction.

It must be noted that information obtained from prospective door suppliers revealed that doors tested by them in the past were tested open outwards. Therefore, it could imply that most, if not all, tested doors in the past were tested open outwards. In the case of single-action hinged doors, this will not give the lowest fire resistance as required by the SANS codes. This way of testing was confirmed by an employee of the SABS fire testing facility.

APPROVAL BY AUTHORITIES AND FIRE ENGINEERS

It appears that a president is established to test doors open outwards and that the results are accepted by the fire chiefs and fire engineers as the fire resistance class irrespective of direction. Therefore, it is required that the authorities, fire chiefs, and fire engineers make a stand and declare if in future fire-door resistance results of open outward doors will be accepted as the fire resistance class irrespective of the direction of application.

There is no prior direction information for fire doors sold at general hardware outlets. The lowest resistance must be applied to those doors because a general door can be applied in any direction. It appears that in South Africa, the direction of testing and reporting was not explicitly addressed and stated in the past.

SUMMARY

There is a trend in the rest of the world to promote bi-directional testing of fire doors. This trend was sparked by the catastrophic failure of the Grenfell apartment block in London. The SANS fire testing codes nonetheless support the bi-directional testing and difference of non-symmetrical door assemblies. It does, however, seem that it is not adhered to by the testing authorities and is also not acknowledged by the approval authorities in South Africa. As a result, we are leaving the door open for legal action against the industry if the codes are not followed unless we waive the code requirements for bi-directional testing to test only from one side, whether opening inwards or outwards.

The fire chiefs and authorities will have to address this point urgently and make the call.

FIRE TESTING TERMS

Thu, 26 Jan 2023 11:43:10 +0200

TERMS AND CONDITIONS FOR SANS 10177:2 FIRE RESISTANCE TESTING

The client must supply and deliver a complete test sample delivered to the test facility at its own costs.
A 50% deposit is required before the sample is delivered to the test facility or a date for the test being confirmed. No refund will be made in the event that a test sample is not submitted.
Balance of payment must reflect in Ignis Testing’s bank account the day before the test is performed.
All prices quoted are valid for 14 days only and are priced (ex VAT). VAT will be charged additional to the rates quoted.
The client will have to resubmit at its cost a new test sample if a test should fail for any reason whatsoever.
No testing or report shall be conducted or issued until payment in full has been received by the Ignis Testing.
It is the duty of the client to submit detailed scaled CAD drawings inclusive of all dimensions and notes. Two cross sections in two orthogonal planes and a front view of the test sample is required.
No test will be performed until the complete and correct CAD drawings is submitted. Additional cost will be charged as quoted, if Ignis Testing is mandated to prepare the CAD drawings.
It is the duty of the client to ensure that Ignis Testing is issued with a complete set of information about the test sample such as type of intumescent, densities, models, brand names etc.
The client is responsible to clearly indicate which side of the test sample is the exposed side.
A sample must be tested twice if it is not symmetrical but can be applied in both directions.
Special installation instructions must be submitted by the client. A failure to do so may impact the final test result and the client will have to conduct an additional test at its cost.
Ignis Testing will not be liable for any claims against the client and / or by the client in the event that a test report reflects negative results.
The client must notify Ignis Testing if there is a suspicion that noxious fumes or toxic gasses could be emitted at test temperatures.
Ignis Testing reserves the right to terminate a test prematurely in the event of excessive smoking, irritating fumes, explosive material or any phenomena which could have health and safety risks or contravene the Health and Safety Act 85 of 1993.
Ignis Testing will not be responsible to refund any amounts in the event of a failed test or a test which had to be terminated prematurely.
The test report is only valid for a period of 5 (five) years from date of testing and strictly applies only to the design quality, material and assembly submitted and tested.
The client must indicate to Ignis Testing if a test is to be done in conjunction with additional codes eg. SANS 1253 for doors, SANS 193 for dampers etc.
Ignis Testing reserves the right to report on any observation or information which is relevant and applicable whether it is positive or negative.
Only Ignis testing can make amendments to its report/s. Any alterations made to a final test report by the client will void the report as a whole and is deemed an offence punishable by law.
Ignis Testing has the right to communicate with fire chiefs and fire engineers on request w.r.t. issued test reports and the performed tests.
Ignis Testing is under no obligation to consult or advise the client about a test outcome and any possible amendments.
Ignis Testing has the right to increase or decrease test and performance parameters within the ambit of the relevant test codes.
Ignis testing at its sole discretion, which may be withheld for any reason whatsoever, reserves the right to extend a test report validity period at additional cost to the client, if it has been furnished satisfactory proof that the product is exactly equivalent in quality, design, material and structure to the sample originally tested.
The client must ascertain the requirements of the specific code and ensure that the sample is compliant. A non-compliant sample will lead to a non-compliant result.