(a) Trickling filters are classified according to applied
hydraulic loading, including recirculation, in million gallons per
day per acre of filter media surface area and influent organic loadings
in pounds of five-day biochemical oxygen demand (BOD5 ) per day per 1,000 cubic feet of filter media.
The following factors must be used as the basis for the selection
of the design hydraulic and influent organic loadings:
(1) BOD5 concentration
of the influent wastewater;
(2) effectiveness of pretreatment;
(3) type of filter media; and
(4) treatment efficiency required.
(b) A trickling filter may be classified as:
(1) a roughing filter, which provides at least 50%,
but not more than 75% removal of soluble BOD5 ;
(2) a secondary treatment filter, which provides the
removal of pollutants required to meet the effluent limits for BOD5 and total suspended solids (TSS) of effluent
set 1 or 2 in §309.4 of this title (relating to Table 1, Effluent
Limitations for Domestic Wastewater Plants);
(3) a combined BOD5 and
nitrifying filter, which provides the removal of pollutants required
to meet the effluent limits for BOD5 ,
ammonia-nitrogen (NH3 -N), and TSS of
effluent set 2N or 2N1 in §309.4 of this title; or
(4) a tertiary nitrifying filter, which provides removal
of NH3 -N, if the influent to the trickling
filter is a clarified secondary effluent.
(c) The following table lists the hydraulic and organic
loadings for different classes of trickling filters.
Attached Graphic
(d) Pretreatment.
(1) A trickling filter must have upstream preliminary
treatment units that:
(A) remove grit, debris, suspended solids, oil, and
grease;
(B) remove particles with a diameter greater than three
millimeters; and
(C) control the release of hydrogen sulfide.
(2) A primary clarifier equipped with scum and grease
removal devices must precede a rock media trickling filter.
(e) Rock Filter Media.
(1) Materials.
(A) Rock filter media composed of crushed rock, slag,
or similar material is prohibited if more than 5% of the media, by
weight, consists of pieces with their longest dimension measuring
more than three times greater than their shortest dimension.
(B) Rock filter media must conform to the following
size distribution and grading. Mechanical grading over a vibrating
screen with square openings must meet the following:
(i) passing 5.0 inch sieve - 100% by weight;
(ii) retained on 3.0 inch sieve - 95 to 100% by weight;
(iii) passing 2.0 inch sieve - 0.2% by weight;
(iv) passing 1.0 inch sieve - 0.1% by weight; and
(v) the loss of weight by the 20-cycle test, as described
in American Society of Civil Engineers' Manual
of Engineering and Engineering Practice No. 13, must be less
than 10%.
(2) Placement.
(A) Rock filter media must be at least 4.0 feet deep
at the shallowest point.
(B) Dumping rock filter media directly on a trickling
filter is prohibited. Rock media must be placed by hand to a depth
of 12 inches above the underdrains. The remainder of the rock filter
media may be placed by belt conveyor or an equivalent mechanical method.
(C) Crushed rock, slag, and other similar media must
be washed and screened or forked to remove clay, organic material,
and other fine particles prior to placement.
(D) The placement of any material must not damage the
underdrains.
(E) Vehicles and equipment are prohibited from driving
over the rock filter media.
(f) Synthetic (Manufactured or Prefabricated) Media
Materials.
(1) Any synthetic media material must be used in accordance
with all of the manufacturer's recommendations.
(2) Synthetic media material may be considered innovative
or non-conforming technology and may be subject to §217.7(b)(2)
of this title (relating to Types of Plans and Specifications Approvals),
and requires executive director approval in writing.
(A) Suitability. The suitability of synthetic media
material must be evaluated based on performance data from a wastewater
treatment facility with similar media operating under similar hydraulic
and organic loading conditions. The engineering report must include
a relevant case history involving the use of the synthetic media.
(B) Durability. A synthetic media must be insoluble
in wastewater and resistant to flaking, spalling, ultraviolet degradation,
disintegration, erosion, aging, common acids and alkalis, organic
compounds, and biological attack.
(C) Structural Integrity.
(i) The structural design of synthetic filter media
must support the synthetic media, water flowing through or trapped
in voids, and the maximum anticipated thickness of the wetted biofilm.
(ii) The synthetic filter media must support the weight
of an individual, unless a separate provision is made for maintenance
access to the entire top of the trickling filter media and to the
distributor.
(D) Placing of Synthetic Filter Media. Modular synthetic
filter media must be installed with the edges of the modules matched
as closely as possible to provide consistent hydraulic conditions
within the trickling filter.
(g) Trickling Filter Dosing.
(1) Dosing rates to a trickling filter must be within
the design dosing rate range, even if the trickling filter receives
flow from a siphon, pump, or gravity discharge from a preceding treatment
unit.
(2) A trickling filter must be designed to control
instantaneous dosing rates under both normal operating conditions
and filter-flushing conditions.
(3) The distributor speed and the recirculation rate
of a trickling filter must be adjusted for the dosing intensity as
a compensatory measure under low-flow conditions. The following table
provides design ranges of dosing intensity for both normal usage periods
and for flushing periods:
Attached Graphic
(4) A design may be based on instantaneous dosing intensity
for rotary distributors using Equation G.1. in Figure: 30 TAC §217.182(g)(4).
Attached Graphic
(h) Distribution Equipment.
(1) The design of a trickling filter must include a
rotary, horizontal, or traveling wastewater distribution system that
distributes wastewater uniformly over the entire surface of a filter
at the design and flushing dosing intensities.
(2) A design must include filter distributors that
operate properly at all anticipated flow rates.
(3) A design must not deviate from the design dosing
intensity by more than 10%.
(4) A new trickling filter or an upgrade of an existing
trickling filter must include an electrically driven, variable speed
filter distributor to allow operation at optimum dosing intensity
independent of recirculation pumping.
(5) If an existing rectangular trickling filter is
retrofitted with rotary distributors, any filter media that will not
be fully wetted must not be considered part of the required effective
treatment area.
(6) The center column of a rotary trickling filter
distributor must have emergency overflow ports that are sized to prevent
water from reaching the bearings in the center column.
(7) A filter distributor must include cleanout gates
on the ends of the distributor arms and an end spray nozzle to wet
the edges of the trickling filter media.
(8) The trickling filter walls must extend at least
12.0 inches above the top of the ends of the distributor arms.
(9) The use of a mercury seal in a distributor of a
trickling filter is prohibited in a new wastewater treatment facility.
If an existing wastewater treatment facility is materially altered,
any mercury seal in a trickling filter must be replaced with an oil
or mechanical seal.
(10) The minimum clearance between the top of the trickling
filter media and the distributing nozzles is 6.0 inches.
(11) Rotary distributors must be capable of operating
at speeds as low as one revolution per 30 minutes.
(12) A trickling filter with a height or diameter that
does not allow distributors to be removed and replaced by a crane
must provide jacking columns and pads at the distributor column.
(i) Recirculation.
(1) Low Flow Conditions.
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