NR 664.1033(3)
(3) Design and operate an enclosed combustion device (e.g., a vapor incinerator, boiler or process heater) to reduce the organic emissions vented to it by 95 weight percent or greater; to achieve a total organic compound concentration of 20 ppmv, expressed as the sum of the actual compounds, not carbon equivalents, on a dry basis corrected to 3 percent oxygen; or to provide a minimum residence time of 0.50 seconds at a minimum temperature of 760
°C. If a boiler or process heater is used as the control device, introduce the vent stream into the flame zone of the boiler or process heater.
NR 664.1033(4)(a)(a) A flare shall be designed for and operated with no visible emissions as determined by the methods specified in sub.
(5) (a), except for periods not to exceed a total of 5 minutes during any 2 consecutive hours.
NR 664.1033(4)(c)
(c) Use a flare only if the net heating value of the gas being combusted is 11.2 MJ/scm (300 Btu/scf) or greater if the flare is steam-assisted or air-assisted, or if the net heating value of the gas being combusted is 7.45 MJ/scm (200 Btu/scf) or greater if the flare is nonassisted. Determine the net heating value of the gas being combusted by the methods specified in sub.
(5) (b).
NR 664.1033(4)(d)1.1. Design a steam-assisted or nonassisted flare for and operate it with an exit velocity, determined by the methods specified in sub.
(5) (c), less than 18.3 m/s (60 ft/s), except as provided in subds.
2. and
3. NR 664.1033(4)(d)2.
2. A steam-assisted or nonassisted flare designed for and operated with an exit velocity, determined by the methods specified in sub.
(5) (c), equal to or greater than 18.3 m/s (60 ft/s) but less than 122 m/s (400 ft/s) is allowed if the net heating value of the gas being combusted greater than 37.3 MJ/scm (1,000 Btu/scf).
NR 664.1033(4)(d)3.
3. A steam-assisted or nonassisted flare designed for and operated with an exit velocity, determined by the methods specified in sub.
(5) (c), less than the velocity, V
max, determined by the method specified in sub.
(5) (d) and less than 122 m/s (400 ft/s) is allowed.
NR 664.1033(4)(e)
(e) Design and operate an air-assisted flare with an exit velocity less than the velocity, V
max, determined by the method specified in sub.
(5) (e).
NR 664.1033(4)(f)
(f) A flare used to comply with this section shall be steam-assisted, air-assisted or nonassisted.
NR 664.1033(5)(a)(a) Use Method 22 in appendix A of
40 CFR part 60, incorporated by reference in s.
NR 660.11, to determine the compliance of a flare with the visible emission provisions of this subchapter. Use an observation period of 2 hours according to Method 22.
NR 664.1033(5)(b)
(b) Calculate the net heating value of the gas being combusted in a flare using the following equation:
where:
HT = Net heating value of the sample, MJ/scm; where the net enthalpy per mole of offgas is based on combustion at 25°C and 760 mm Hg, but the standard temperature for determining the volume corresponding to 1 mol is 20 °C
K = Constant, 1.74×10-7 (1/ppm) (g mol/scm) (MJ/kcal) where standard temperature for (g mol/scm) is 20°C
C
i = Concentration of sample component i in ppm on a wet basis, measured for organics by Method 18 in appendix A of
40 CFR part 60 and measured for hydrogen and carbon monoxide by ASTM D1946-82, both incorporated by reference in s.
NR 660.11
H
i = Net heat of combustion of sample component i, kcal/9 mol at 25
°C and 760 mm Hg. The heats of combustion may be determined using ASTM D2382-83, incorporated by reference in s.
NR 660.11, if published values are not available or cannot be calculated
NR 664.1033(5)(c)
(c) Determine the actual exit velocity of a flare by dividing the volumetric flow rate (in units of standard temperature and pressure), determined by Methods 2, 2A, 2C or 2D in appendix A of
40 CFR part 60, incorporated by reference in s.
NR 660.11, as appropriate, by the unobstructed (free) cross-sectional area of the flare tip.
NR 664.1033(5)(d)
(d) Determine the maximum allowed velocity in m/s, V
max, for a flare complying with sub.
(4) (d) 3. by the following equation:
where:
28.8 = Constant
31.7 = Constant
HT = The net heating value determined in par. (b)
NR 664.1033(5)(e)
(e) Determine the maximum allowed velocity in m/s, V
max, for an air-assisted flare by the following equation:
where:
8.706 = Constant
0.7084 = Constant
HT = The net heating value determined in par. (b)
NR 664.1033(6)
(6) The owner or operator shall monitor and inspect each control device required to comply with this section to ensure proper operation and maintenance of the control device by implementing all of the following requirements:
NR 664.1033(6)(a)
(a) Install, calibrate, maintain and operate according to the manufacturer's specifications a flow indicator that provides a record of vent stream flow from each affected process vent to the control device at least once every hour. Install the flow indicator sensor in the vent stream at the nearest feasible point to the control device inlet, but before the point at which the vent streams are combined.
NR 664.1033(6)(b)
(b) Install, calibrate, maintain and operate according to the manufacturer's specifications a device to continuously monitor control device operation according to one of the following:
NR 664.1033(6)(b)1.
1. For a thermal vapor incinerator, a temperature monitoring device equipped with a continuous recorder. The device shall have an accuracy of
±1% of the temperature being monitored in
°C or
±0.5
°C, whichever is greater. Install the temperature sensor at a location in the combustion chamber downstream of the combustion zone.
NR 664.1033(6)(b)2.
2. For a catalytic vapor incinerator, a temperature monitoring device equipped with a continuous recorder. The device shall be capable of monitoring temperature at 2 locations and have an accuracy of
±1% of the temperature being monitored in
°C or
±0.5
°C, whichever is greater. Install one temperature sensor in the vent stream at the nearest feasible point to the catalyst bed inlet and install a second temperature sensor in the vent stream at the nearest feasible point to the catalyst bed outlet.
NR 664.1033(6)(b)3.
3. For a flare, a heat sensing monitoring device equipped with a continuous recorder that indicates the continuous ignition of the pilot flame.
NR 664.1033(6)(b)4.
4. For a boiler or process heater having a design heat input capacity less than 44 MW, a temperature monitoring device equipped with a continuous recorder. The device shall have an accuracy of
±1% of the temperature being monitored in
°C or
±0.5
°C, whichever is greater. Install the temperature sensor at a location in the furnace downstream of the combustion zone.
NR 664.1033(6)(b)5.
5. For a boiler or process heater having a design heat input capacity greater than or equal to 44 MW, a monitoring device equipped with a continuous recorder to measure a parameter or parameters that indicates good combustion operating practices are being used.
NR 664.1033(6)(b)6.a.
a. A monitoring device equipped with a continuous recorder to measure the concentration level of the organic compounds in the exhaust vent stream from the condenser.
NR 664.1033(6)(b)6.b.
b. A temperature monitoring device equipped with a continuous recorder. The device shall be capable of monitoring temperature with an accuracy of
±1% of the temperature being monitored in
°C or
±0.5
°C, whichever is greater. Install the temperature sensor at a location in the exhaust vent stream from the condenser exit (i.e., product side).
NR 664.1033(6)(b)7.
7. For a carbon adsorption system that regenerates the carbon bed directly in the control device such as a fixed-bed carbon adsorber, any of the following:
NR 664.1033(6)(b)7.a.
a. A monitoring device equipped with a continuous recorder to measure the concentration level of the organic compounds in the exhaust vent stream from the carbon bed.
NR 664.1033(6)(b)7.b.
b. A monitoring device equipped with a continuous recorder to measure a parameter that indicates the carbon bed is regenerated on a regular, predetermined time cycle.
NR 664.1033(6)(c)
(c) Inspect the readings from each monitoring device required by pars.
(a) and
(b) at least once each operating day to check control device operation and, if necessary, immediately implement the corrective measures necessary to ensure the control device operates in compliance with this section.
NR 664.1033(7)
(7) An owner or operator using a carbon adsorption system such as a fixed-bed carbon adsorber that regenerates the carbon bed directly onsite in the control device shall replace the existing carbon in the control device with fresh carbon at a regular, predetermined time interval that is no longer than the carbon service life established as a requirement of s.
NR 664.1035 (2) (d) 3. f. NR 664.1033(8)
(8) An owner or operator using a carbon adsorption system such as a carbon canister that does not regenerate the carbon bed directly onsite in the control device shall replace the existing carbon in the control device with fresh carbon on a regular basis using one of the following procedures:
NR 664.1033(8)(a)
(a) Monitor the concentration level of the organic compounds in the exhaust vent stream from the carbon adsorption system on a regular schedule and replace the existing carbon with fresh carbon immediately when carbon breakthrough is indicated. The monitoring frequency shall be daily or at an interval no greater than 20% of the time required to consume the total carbon working capacity established as a requirement of s.
NR 664.1035 (2) (d) 3. g., whichever is longer.
NR 664.1033(8)(b)
(b) Replace the existing carbon with fresh carbon at a regular, predetermined time interval that is less than the design carbon replacement interval established as a requirement of s.
NR 664.1035 (2) (d) 3. g. NR 664.1033(9)
(9) An alternative operational or process parameter may be monitored if it can be demonstrated that another parameter will ensure that the control device is operated in conformance with these standards and the control device's design specifications.
NR 664.1033(10)
(10) An owner or operator of an affected facility seeking to comply with this chapter by using a control device other than a thermal vapor incinerator, catalytic vapor incinerator, flare, boiler, process heater, condenser or carbon adsorption system shall develop documentation including sufficient information to describe the control device operation and identify the process parameter or parameters that indicate proper operation and maintenance of the control device.
NR 664.1033(11)
(11) A closed-vent system shall meet any of the following design requirements:
NR 664.1033(11)(a)
(a) Design a closed-vent system to operate with no detectable emissions, as indicated by an instrument reading of less than 500 ppmv above background determined by the procedure in s.
NR 664.1034 (2), and by visual inspections.
NR 664.1033(11)(b)
(b) Design a closed-vent system to operate at a pressure below atmospheric pressure. Equip the system with at least one pressure gauge or other pressure measurement device that can be read from a readily accessible location to verify that negative pressure is being maintained in the closed-vent system when the control device is operating.
NR 664.1033(12)
(12) The owner or operator shall monitor and inspect each closed-vent system required to comply with this section to ensure proper operation and maintenance of the closed-vent system by implementing all of the following requirements:
NR 664.1033(12)(a)
(a) Inspect and monitor each closed-vent system that is used to comply with sub.
(11) (a) according to all of the following requirements:
NR 664.1033(12)(a)1.
1. Conduct an initial leak detection monitoring of the closed-vent system on or before the date that the system becomes subject to this section. Monitor the closed-vent system components and connections using the procedures in s.
NR 664.1034 (2) to demonstrate that the closed-vent system operates with no detectable emissions, as indicated by an instrument reading of less than 500 ppmv above background.
NR 664.1033(12)(a)2.
2. After initial leak detection monitoring required in subd.
1., inspect and monitor the closed-vent system as follows:
NR 664.1033(12)(a)2.a.
a. Visually inspect closed-vent system joints, seams or other connections that are permanently or semi-permanently sealed (e.g., a welded joint between 2 sections of hard piping or a bolted and gasketed ducting flange) at least once per year to check for defects that could result in air pollutant emissions. Monitor a component or connection using the procedures in s.
NR 664.1034 (2) to demonstrate that it operates with no detectable emissions following any time the component is repaired or replaced (e.g., a section of damaged hard piping is replaced with new hard piping) or the connection is unsealed (e.g., a flange is unbolted).
NR 664.1033(12)(a)2.b.
b. Monitor closed-vent system components or connections other than those specified in subd.
2. a. annually and at other times requested by the department, except as provided for in sub.
(15), using the procedures in s.
NR 664.1034 (2) to demonstrate that the components or connections operate with no detectable emissions.
NR 664.1033(12)(a)3.
3. In the event that a defect or leak is detected, repair the defect or leak according to par.
(c).
NR 664.1033(12)(b)
(b) Inspect and monitor each closed-vent system that is used to comply with sub.
(11) (b) according to all of the following requirements:
NR 664.1033(12)(b)1.
1. Visually inspect the closed-vent system to check for defects that could result in air pollutant emissions. Defects include, but are not limited to, visible cracks, holes or gaps in ductwork or piping or loose connections.
NR 664.1033(12)(b)2.
2. Perform an initial inspection of the closed-vent system on or before the date that the system becomes subject to this section. Thereafter, perform the inspections at least once every year.
NR 664.1033(12)(c)1.
1. Control detectable emissions, as indicated by visual inspection, or by an instrument reading greater than 500 ppmv above background, as soon as practicable, but not later than 15 calendar days after the emission is detected, except as provided for in subd.
3. NR 664.1033(12)(c)2.
2. Make a first attempt at repair no later than 5 calendar days after the emission is detected.
NR 664.1033(12)(c)3.
3. Delay of repair of a closed-vent system for which leaks have been detected is allowed if the repair is technically infeasible without a process unit shutdown, or if the owner or operator determines that emissions resulting from immediate repair would be greater than the fugitive emissions likely to result from delay of repair. Complete repair of the equipment by the end of the next process unit shutdown.
NR 664.1033(13)
(13) Operate closed-vent systems and control devices used to comply with this subchapter at all times when emissions may be vented to them.
NR 664.1033(14)
(14) The owner or operator using a carbon adsorption system to control air pollutant emissions shall document that all carbon that is a hazardous waste and that is removed from the control device is managed in one of the following manners, regardless of the average volatile organic concentration of the carbon:
NR 664.1033(14)(a)
(a) Regenerated or reactivated in a thermal treatment unit that meets one of the following:
NR 664.1033(14)(a)1.
1. The owner or operator of the unit has been issued an operating license under ch.
NR 670 which implements the requirements of subch.
X.
NR 664.1033(14)(b)
(b) Incinerated in a hazardous waste incinerator for which any of the following conditions has been met:
NR 664.1033(14)(b)1.
1. The owner or operator has been issued an operating license under ch.
NR 670 which implements the requirements of subch.
O.
NR 664.1033(14)(c)
(c) Burned in a boiler or industrial furnace for which any of the following conditions has been met:
NR 664.1033(14)(c)2.
2. The owner or operator has designed and operates the boiler or industrial furnace according to the interim license requirements of subch.
H of ch. NR 666.
NR 664.1033(15)(a)
(a) Determines that the components of the closed-vent system are unsafe to monitor because monitoring personnel would be exposed to an immediate danger as a consequence of complying with sub.
(12) (a) 2. b.