The Codes Our Products Are Designed To Exceed

NFPA 101 Life Safety Code 2012 Edition.

4.1.1* Fire. A goal of this code is to provide an environment for the occupants that is reasonably safe from fire by the following means:
(1)* Protection of occupants not intimate with the initial fire development
(2) Improvement of the survivability of occupants intimate with the initial fire development

4.2.3 System Effectiveness. Systems utilized to achieve the goals of section 4.1 shall be effective in mitigating the hazard or condition for which they are being used, shall be reliable, shall be maintained to the level at which they were designed to operate, and shall remain operational.

4.5.1 Multiple Safeguards. The design of every building or structure intended for human occupancy shall be such that reliance for safety to life does not depend solely on any single safeguard. An additional safeguard(s) shall be provided for life safety in case any single safeguard is ineffective due to inappropriate human actions or system failure.

9.6.1.7 For the purpose of this code, a complete fire alarm system shall provide functions for the initiation, notification and control, which shall perform as follows:
(1) The initiation function provides the input signal to the system.
(2) The notification function is the means by which the system advises that human action is required in response to a particular condition.
(3) The control function provides outputs to control building equipment to enhance protection of life.

9.6.6 Location of Controls. Operator controls, alarm indicators, and manual communications capability shall be installed at a convenient location acceptable to the authority having jurisdiction.

NFPA 45

NFPA 45 – Standard on Fire Protection For Laboratories Using Chemicals, 2011 Edition

6.6 Fire Prevention

6.6.1 Fire prevention procedures.

6.6.1.1 Fire prevention procedures shall be established.

6.6.3* Emergency Plans

6.6.3.1 Plans for laboratory emergencies shall be developed, which shall include the following:
(1) Alarm activation
(2) Evacuation and building re-entry procedures
(3) Shutdown procedures or applicable emergency operations for equipment, processes, ventilation devices, and enclosures
(4) Fire fighting operations
(5)* Non-fire hazards
(6) Information as required by the AHJ to allow the emergency responders to develop response tactics

7.1 Explosion Hazard Protection

7.12 Protection shall be provided by one or more of the following:
(4) Remote control of equipment to minimize personnel exposure

12 Laboratory Operations and Apparatus.

12.1.1.6 Unattended or automatic laboratory operations involving hazardous chemicals shall be provided with regular surveillance for abnormal conditions. (see 12.1.2.4 and 12.2.4.1)

12.1.2.4 Unattended operations shall be provided with over-ride control and automatic shutdown to prevent systems failure that can result in fire explosion.

12.2.1.2 Operating controls shall be accessible under normal and emergency conditions.

NFPA 30

NFPA 30 Flammable and Combustible Liquids Code, 2012 Edition

6.6.2 Those areas, including buildings, where a potential exists for a flammable liquid spill shall be monitored as appropriate. The following methods shall be permitted to be used:

(1) Personnel observation or patrol
(2) Process-monitoring equipment that would indicate a spill or leak could have occurred
(3) Provision of gas detectors to continuously monitor the area where facilities are unattended

NFPA 1

NFPA 1 Fire Code 2018 Edition

4.4.1 Multiple Safeguards
4.4.1.1 The design of every building or structure intended for human occupancy shall be such that reliance on property protection and safety to life does depend solely on any single safeguard.

4.4.1.2 Additional safeguard(s) shall be provided for property protection and life safety in the event that any single safeguard is ineffective due to inappropriate human actions, building failure or system failure.

4.4.2 Appropriateness of Safeguards. Every building or structure shall be provided with means of egress and other safeguards of the kinds, numbers, locations, and capacities appropriate to the individual building or structure, with due regard to the following:

(1) Characteristics of the occupancy
(2) Capabilities of the occupants
(3) Number of persons exposed
(4) Fire protection available
(5) Capabilities of response personnel
(6) Height and type of construction of the building or structure
(7) Other factors necessary to provide occupants with a reasonable degree of safety
(8) Other factors necessary to protect the building and contents from danger

4.5.3 Provisions in Excess of Code Requirements. Nothing in this code shall be construed to prohibit a better type of building construction, an additional means of egress, or an otherwise more safe condition than that specified by the minimum requirements of this code.

NFPA 54

NFPA 54 – National Fuel Gas Code

5.12 Shutoff Valves. Shutoff valves shall be approved and shall be selected giving consideration to pressure drop, service involved, emergency use, and reliability of operation. Shutoff valves of 1 in. (25mm) National Pipe Thread and smaller shall be listed.

7.9.2.4 Shutoff Valves for Laboratories. Each laboratory space containing two or more gas outlets installed on tables, benches, or in hoods in educational, research, commercial, and industrial occupancies shall have a single shutoff valve through which all such gas outlets are supplied. The shutoff valve shall be accessible, located within the laboratory or adjacent to the laboratory’s egress door, and identified.

NSTA

NSTA – Electricity P34

“Manual shut-off switches should be located so that the teacher can easily access them and shut off the electricity, gas or water in different zones when not needed for science activities”

“Emergency shut-off controls for electrical or gas service should be highly visible, clearly labeled, and available to the teacher, but not easily accessible to the students. They are normally located near the teacher’s station and not far from the hallway exit, but not immediately adjacent to the hall door. The placement should be such so that the students are not able to hit the switch as they exit the class each period causing repetitive problems.”

NSTA Heat Sources P34

“The clearly labeled emergency gas shut-off valve should be activated by pushing a highly visible button, with a keyed reset mechanism to turn the gas supply back on when the emergency is over. The keyed reset feature can also be used by the teacher to shut off the gas when it is not needed in lieu of the control valve mentioned above. Models that have red shut off buttons recessed into a metal frame minimize the possibility of an inadvertent shutoff. All emergency controls in the laboratory / classroom should be in a location that is readily accessible by the teacher, but not easily reached by students.”

NSTA Utilities P63

Designing Facilities for the Middle School (6-8)

“If central gas is used, it should be located at the perimeter, near the sinks. The room should have a button-activated emergency shut-off valve.”

“Place emergency shut-off controls for electrical service, and gas near the teacher’s station, not far from the door, and not too easily accessible to students.”

NSTA Utilities P81

Designing Facilities for the High School (9-12)

“When gas is provided by a central system, an emergency shut-off valve, activated by pushing a highly visible visible button, will be needed. A central control valve can enable the teacher to shut off the gas in the room when not in use. Emergency shut-off controls for electrical service and gas should be near the teacher’s station, not far from the door, and not easily accessible to students.”

IMC 2021

409.6 Shutoff valve for laboratories.
Where provided with two or more fuel gas outlets, including table-, bench- and hood-mounted outlets, each laboratory space in educational, research, commercial and industrial occupancies shall be provided with a single dedicated shutoff valve through which all such gas outlets shall be supplied. The dedicated shutoff valve shall be readily accessible, located within the laboratory space served, located adjacent to the egress door from the space and shall be identified by approved signage stating “Gas Shutoff.”

[F] 907.2.3 Group E.
A manual fire alarm system that initiates the occupant notification signal utilizing an emergency voice/alarm communication system meeting the requirements of Section 907.5.2.2 and installed in accordance with Section 907.6 shall be installed in Group E occupancies. When automatic sprinkler systems or smoke detectors are installed, such systems or detectors shall be connected to the building fire alarm system.

404.3.1 Fire evacuation plans.
Fire evacuation plans shall include the following:
2. Procedures for employees who must remain to operate critical equipment before evacuating.
6. The preferred and any alternative means of notifying occupants of a fire or emergency.

ASME CSD-1

‘(b) A manually operated remote shutdown switch or circuit breaker shall be located just outside the boiler room door and marked for easy identification.

(1) Consideration should be given to the type and locations of remote shutdown switch to safeguard against tampering. If the boiler room door is on the building exterior, the switch should be located just inside the door. If there is more than one door to the boiler room, there should be a remote shutdown switch located at each door.
(2) Activation of the remote switch or circuit breaker shall immediately shut off the fuel or energy supply.’

NFPA 54

NFPA (54) Code 10.3.5.1 & 10.3.5.2 (2002)

‘Ventilating hoods and exhaust systems shall be permitted to vent gas-fired equipment installed in commercial applications. However, certain requirements must be met, including:
• These same requirements apply for systems with standing or electronic pilot ignitions.
• A valve shall be located on the main gas line feeding the appliances served by the gas hood and shall stop the flow of gas to the appliances upon loss of draft. No by-pass of the gas solenoid valve is allowed.
• Where automatically operated gas utilization equipment is vented through a ventilating hood or exhaust system equipped with a damper or with a power means of exhaust, provisions shall be made to allow the flow of gas to the main burners only when the damper is open to a position to properly vent the equipment and when the power means of exhaust is in operation.
• The gas valve must be controlled by a draft proving switch measuring draft within the hood. The gas valve is allowed to be open only when the fan is operational or the damper is 100% open.
• The gas valve shall be equipped with a manual reset (integral or otherwise). The valve must be manually reset only when the lock-out condition is corrected. The reset cannot be automatic.’

NFPA (54) Code 10.12.8 (2018)

‘Means shall be provided to properly ventilation the space in which a food service appliance is installed to permit proper combustion of the gas.’

NFPA (54) Code 12.4.4.1 (2021)

‘Where automatically operated appliances, other than food service appliances, are vented through a ventilation hood or exhaust system equipped with a damper or with a power means of exhaust, provisions shall be made to allow the flow of gas to the main burners only when the damper is open to a position to properly vent the appliance and when the power means of exhaust is in operation.’

The Merlin range of Ventilation Interlocking Systems ensures ventilation is operational or dampers are 100% open by monitoring the air flow through an air pressure differential switch. In the event of ventilation failure or if the exhaust fans are not in operation, the Merlin range will automatically shutdown the gas supply thru a gas solenoid valve and will require a manual reset after the method of ventilation is functioning.

NFPA 96

NFPA (96) Code 4.1.4 (2021)

‘All airflows shall be maintained.’

NFPA (96) Code 8.2.3.3 (2021)

‘The exhaust fan shall be provided with a means so that the fan is activated when any heat-producing cooking appliances under the hood is turned on.’

NFPA (96) Code 9.3.7 (2021)

‘If the heat source is non-electric and open flames are used, a carbon monoxide detector shall be installed in both the kitchen and dining areas’.

NFPA (96) Code 12.1.1 (2021)

‘Exhaust systems shall be operated whenever cooking equipment is turned on.’

NFPA 54

NFPA (54) Code 10.3.5.1 & 10.3.5.2 (2002)

NFPA (54) Code 10.12.8 (2018)

‘Means shall be provided to properly ventilation the space in which a food service appliance is installed to permit proper combustion of the gas.’

NFPA (54) Code 12.4.4.1 (2021)

NECB A-5.2.3.4.(1)

Enclosed Spaces Where Fuel-Powered Equipment is Used

Examples of enclosed spaces targeted by Sentence 5.2.3.4.(1) are indoor sports arenas where fuel-powered equipment is used for maintenance of the play area (such as an ice-surfacing vehicle in an ice-rink arena), warehouses with propane-fueled forklifts, and heated indoor storage garages. In such spaces, contaminant levels are often controlled through on-and-off staging of a dedicated fan system. However, some ventilation systems use variable-speed fans to modulate between a set minimum (which can be as low as 0 when the contaminant levels are low enough) and the peak airflow rates needed to control the levels of contaminants in the air. Air contaminants generally controlled by such systems are carbon monoxide (CO) and nitrous oxides (NOx), depending on the type of fuel used.

Spaces where fuel-powered vehicles or mobile fuel-powered equipment or appliances are used on a semi-continuous basis (e.g., multiple forklifts actively used in a distribution warehouse) may be exempted from complying with Sentence 5.2.3.4.(1), subject to the approval of the authority having jurisdiction. However, some standards, such as ANSI/ASHRAE 62.1, “Ventilation for Acceptable Indoor Air Quality,” still require a minimum ventilation rate based on occupancy or other activities carried out in the space. It is expected that a means will be provided to evacuate exhaust air from fixed fuel-powered appliances and equipment directly to the outdoors. Thus, only spaces where vehicles or mobile equipment or appliances with combustion engines are used are targeted by this requirement.

General

“Instead of providing constant airflow at peak design rates like traditional ventilation systems, demand control ventilation systems include strategies designed to modulate the minimum outdoor airflow rates required for some applications, based on a dynamic variable such as transient occupancy or vented process use.

Demand control ventilation is recognized as being an effective energy efficiency measure for certain applications and the strategies listed in Article 5.2.3.4. are deemed reliable. However, the effectiveness of other demand control ventilation strategies can vary significantly according to the application for which they are being used and their implementation, occupant density, and the type, placement and calibration of the sensor.

Most notably, the improper implementation of CO2-based demand control ventilation systems that modulate outdoor airflow rates to occupied spaces can lead to the over- or under-ventilation of the spaces, resulting in either excessive energy use or health and safety issues for the occupants. Thus, demand control ventilation strategies should be implemented in accordance with the latest best practices. See ASHRAE publications or other applicable documents for additional information.”

IMC 2021

404.1 Enclosed Parking Garages

Mechanical ventilation systems for enclosed parking garages shall operate continiuously or shall be automatically operated by means of carbon monoxide detectors applied in conjunction with nitrogen dioxide detectors. Such detectors shall be listed in accordance with UL 2075 and installed in accordance with their listing and the manufacturer’s instructions.

CSA B52--05

6.2.3 Refrigerant Vapour Detector

For all refrigerants, except ammonia, the detector shall:

be located in an area where refrigerant from a leak is most likely to concentrate
actuate at a value not greater than the TLV/TWA
sound an audible alarm
initiate mechanical ventilation

“in certain situations, more than one detector can be necessary”

6.2.4.3 Explosion Protection

combustion equipment may be installed in the same machinery room when a refrigerant vapour detector is employed to shut down combustion equipment

6.2.5.4 Fan Switches

shall be accessible inside and outside the machinery
shall be capable of starting but not stopping the ventilation

6.3 (h),(i) Class T Machinery Rooms

remote pilot control outside the machinery room for shutting down the equipment
vapour detector shall initiate alarm for corrective action

8.4.1 (d) Maintenance

shall be tested in accordance with manufacturer’s instructions
maximum interval not to exceed one year
test shall initiate audible, visual and ventilation

ASHRAE 15 2022

8.9 Refrgierating Machinery Room, General Requirements.

When a refrigerating system is located indoors and a machinery room is required by section 7.4, the machinery room shall be in accordance with the following provisions.

8.9.5 Each refrigerating machinery room shall contain a detector, located in an area where refrigerant from a leak will concentrate, that actuates an alarm and mechanical ventilation in accordance with Section 8.9.7 at a set point not greater than the occupational exposure limit (OEL) value as published in ASHRAE 34. For refrigerants that do not have a published OEL value in Standard 34, a set point determine in accordance with OEL as designed by Standard 34 shall be approved by the AHJ. The alarm shall annunciate visual and audible alarms inside the refrigerating machineryr room and outside each entrance to the refrigerating machinery room. The alarms required in this section shall be of the manual reset type with the reset located inside hte refrigeranting machinery room. Alarms set at other levels (such as IDLH) and automatic reset alarms are permitted in addition to those required by this section. The meaning of each alarm shall be clearly marked by signage near the annunciators.