Figure
1. A conceptual approach to RRR operation illustrating a peak flow of a
river i.e., red phase that can be potentially stored by RRR and a
corresponding regulated flow release back into the river i.e., bule
phase. a) illustrates a hypothetical image of RRR and a river; b)
presents a conceptual hydrograph of the river flow starting from
upstream of the HPP and progressing downstream of RRR. Google Earth
9.185, (2020) Petäjäskoski, 66° 16’ 10” N, 25° 20’ 17” E elevation 49m.
[Online] Available at: https://earth.google.com [Accessed 5
March 2023].
Hydrological and Ecological Criteria for Hydropeaking
Mitigation
The hydrologic alteration in a river can be governed on spatial and
temporal scales through a change in magnitude, rate of flow change,
frequency, and duration of flow. Any deviation from the natural states
of these parameters is associated with a discrete environmental impact
(Haghighi et al., 2014). Thus, to minimize the impact, variations in
these parameters should be restricted to thresholds. However, despite
extensive research on hydropeaking, only a few European countries (i.e.,
Switzerland and Austria) have national regulations defining hydropeaking
thresholds (Moreira et al., 2019). While current literature mainly
focuses on qualitative targets, setting thresholds and targets for the
aforementioned factors is still considered a challenge. There is still a
lack of consensus to specify thresholds for the mentioned parameters
(Costa et al., 2017).
The main adverse impact of down ramping is fish stranding and changes in
habitat locations, which results in major ecological pressure on the
river (Nagrodski et al., 2012). Besides down ramping rates, minimum flow
and peak flow magnitudes affecting spawning and intra-gravel life stages
are also important factors to consider (Moreira et al., 2019). Up
ramping rate presents one additional factor that can cause fish drift
and impact the ecological conditions. In terms of water uses, flow
fluctuations caused by hydropeaking can be intense and disruptive for
existing irrigation schemes (Bieri et al, 2016) and negatively impact
recreational activities such as fishing, kayaking, and swimming
(Charmasson et al., 2011). Finally, hydropeaking can worsen the drinking
water quality by stirring up sediments and other pollutants. Therefore,
in this study, we will focus on how RRRs can contribute to flow
management, including ramping rates, minimum flow, and peak flow which
are critical criteria for hydropeaking mitigation (Moreira et al., 2019
& Richter et al., 2010).
Model-based Design Development
A full restoration of a river regime to its natural state requires a
large RRR volume which might not always be feasible due to economic or
land availability constraints. However, shaving the peak flow,
increasing the minimum flow, and limiting ramp rates can substantially
restore the river regime to its natural state. Such objectives could be
resolved with RRRs which necessitate flows to be retained and adequately
released into the waterway (Fig.1). Inadequate (i.e., too slow) water
release might result in small volume availability in the RRR to
accommodate water from peak flows and up-ramping events. Thus, to
effectively manage RRRs, a model is required to determine the timing and
amount of water that needs to be stored or released. Once this is
achieved, the model can calculate the required RRR volume. With this
mind, the theoretical foundation of the model developed in this study
was based on two main objectives. The primary objective of the RRR is to
reduce the hourly peak flow (Qmax) and increase the
minimum hourly flow (Qmin) induced by hydropeaking.
Secondarily, the RRR aims to reduce the up- and down- ramping rates and
increase the timespan during flow change occurs. The ramping flow rate
(∆Q(t)) [m3s-1min-1] given in equation (Eq.
1), represents the increase (i.e., up ramping, positive values) or
decrease (down ramping, negative values) in the flow over a given time
step, where, Q(t) is the discharge at time t
(m3.s-1), Q(t - ∆t) is the discharge
at time t- ∆t (m3.s-1) and ∆t is the
time step (min).
\(Q\left(t\right)=\frac{Q\left(t\right)-Q(t-t)}{t}\) (Eq. 1)
A flow pattern resembling a regulated river regime exposed to frequent
hydropeaking was needed to design the model. For this purpose, Kemijoki
River, one of the most regulated rivers in Finland, with a mean annual
discharge of 515 m3s-1 (Ashraf et
al., 2016) was selected and hourly discharge data for the lower part of
the main river channel of the Taivalkoski HPP from 2015 to 2017 was
obtained from national datasets maintained by the Finnish Environment
Institute (Hertta-database, for more details, see Ashraf et al., 2016).
To generate the required flow pattern (hereinafter called scaled flow),
characterized by an average discharge of 1
m3.s-1, the Taivalkoski HPP
discharge data was scaled down by dividing the hourly discharge by the
average hourly discharge per day (Eq. 2).
\(Q_{\text{scaled}}\ (t)=\frac{Q\left(t\right)}{Q_{\text{avg}}(d)}\)(Eq. 2)
Where Qscaled (t) is the scaled discharge at time t
(m3.s-1), Q (t) is the actual
discharge at time t (m3.s-1), and
Qavg (d) is the average hourly discharge per day
(m3.s-1).
Once the scaled flow is attained, it is possible to establish a
hierarchy of operational objectives with a range of distinct thresholds
that dictate the timing and amount of water that needs to be stored or
released by the RRR. Thus, a re-regulation algorithm that operates the
RRR based on the following list of hierarchal objectives and their
associated thresholds was developed;
- Priority 1, Reliability and Safety: the inflow and outflow discharges
would not lead to the overflow or the depletion of the re-regulation
basin in the next time step.
- Priority 2, Peak and Minimum flows: the operation of the re-regulation
basin would reduce the peak flow and increase the minimum flow by 10
to 50% (hereinafter referred to as flow adjustment). Thus, the peak
flow is limited between 50 and 90%×Qmax and the minimum flow between
110 and 150%×Qmin.
- Priority 3, Maximum Up- and Down-ramping rates: up-ramping rates are
limited to a distinct threshold when the flow is greater than the
average daily flow. Down-ramping rates are limited to a distinct
threshold when the flow is smaller than the average daily flow. The
investigated thresholds for up and down ramping rates (r.r) are 1,
1.5, 2, 2.5, 3, 3.5, 4, and -1, -1.5, -2, -2.5, -3, -3.5, -4
m3sec-1min-1,
respectively. To include these r.r thresholds in the scaled flow
re-regulation algorithm, they had to be scaled down according to
equation (Eq. 3)\(\text{r.\ r}_{\text{scaled}}=\ \frac{\text{r.r}}{Qavg(a)}\) (Eq.
3)
Where r.r scaled is the scaled r.r threshold
(m3sec-1min-1),
r.r is the unscaled r.r threshold, and Qavg(a) is the
annual average discharge
(m3sec-1).
- Priority 4, Optimal flow: A flow is restored to a daily average flow
whenever possible.
- Priority 5, Optimal up and down ramping rates: Whenever possible, the
ramping rate thresholds are satisfied regardless if the flow is
greater or smaller than the average daily flow.
As the ideal flow conditions for the various ecosystem services may be
different, a range of thresholds was utilized in the algorithm to
determine the required RRR volume for several hydropeaking mitigation
scenarios. Thus, the threshold range for flow magnitude was selected to
include all the possible mitigation scenarios, by using 10% flow
adjustment increments. Whereas, the ramping rate thresholds were
carefully chosen to include a range of scenarios, by incrementally
adjusting the lower and upper limits of the range. The threshold range
started from a threshold below the average ramping rate and was extended
to reach up to 50% of the maximum ramping rate, using increments of 0.5
m3sec-1min-1. The
unscaled average up- and down- ramping rates downstream of Taivalkoski
HPP during 2015 to 2017 were 1.5085 and -1.36
m3sec-1min-1,respectively. As such, the lower limit for ramping rate threshold was
set to 1
m3sec-1min-1.
Whereas the maximum unscaled ramping rate reached up to 8
m3sec-1min-1, as
such the upper limit for the ramping rate threshold range was set to 4
m3sec-1min-1. To
further expand the scope of possible mitigation scenarios, thirty-five
permutations were created and tested by matching the peak and minimum
flow thresholds (i.e., priority 2) with ramp rate thresholds (i.e.,
priority 3). Hereinafter, the permutations will be referred to as P
(X%, Y), with X% being the percentage adjusted from Qmax and Qmin
i.e., (100-X) %×Qmax and (100+X) %×Qmin, while Y is the ramp rate
threshold i.e., (Y) for up-ramping and (-Y) for down-ramping. One
example from the permutations is P (10%, 2.5) which matches the 10%
flow adjustment (i.e., 90%*Qmax and 110%*Qmin threshold) with a ramp
rate threshold of 2.5
m3s-1min-1.
Additionally, we demonstrate how the RRR would re-regulate the flow
downstream of Taivalkoski (Kemijoki) for permutation P (40%, 2) by
using the re-regulation algorithm.
This model was used to determine the required volume of RRRs downstream
of HPPs operating at the Kemijoki River. It has the potential to be
utilized in other rivers with similar flow patterns to achieve the above
listed priorities. However, the range of thresholds employed by the
re-regulation algorithm must be modified to best suit the flow pattern
of the investigated river. It is important to note the model assumes the
location of the RRR is immediately downstream of the HPP, thus not
accounting for flow velocity or the time required for water to reach the
RRR. The model also assumes ideal RRR conditions with no consideration
of any water losses that might occur due to evaporation and seepage.
Results
Table 1. presents our calculations showing clear theoretical
possibilities for regulating hydropeaking with RRRs. For example,
assuming that the future flow is consistent with the scaled flow of the
study period, the required RRR volumes (Table 1) are sufficient to
ensure the hydropeaking thresholds are respected throughout the year.
The results indicate that, for most of the tested permutations, the
required volume of the RRRs increased as the thresholds for peak and
minimum hourly flows and the ramping rates became more stringent.
Nonetheless, for some permutations, this trend was not observed. One
example is the required RRR volume for permutations P (10%, 3.5,
volume: 0.256 million cubic meters (MCM)) and P (10%, 4, volume: 0.368
MCM) are larger than the reservoir volume needed for permutations P
(10%, 2.5, volume: 0.147) and P (10%, 3, volume: 0.143) which have
more stringent ramp rate threshold. Furthermore, for permutation P
(10%, 4), the required RRR volume (0.368 MCM) decreases slightly
compared to P (20%, 4, volume: 0.262 MCM), which has more stringent
peak and minimum flow thresholds. Our theoretical approach demonstrates
the relationship between the required RRR volume, daily peak discharge,
and ramp rate thresholds (Figure 2).
Furthermore, the required RRR volume was determined for each month
separately, illustrated in Figure 3. The results indicate that for most
of the investigated permutations except permutations with 50% flow
adjustment, July and August require the largest reservoir volume to
achieve the objectives and priorities stated in section 2.3. Whereas,
for permutations with a 50% flow adjustment, January is the month that
requires the largest reservoir volume. However, it is important to note
that January and February are the months with largest volume requirement
when the ramp rate thresholds exceed 2.5
m3.s-1.min-1 for
permutations with a 10% flow adjustment. Additionally, the RRR
operation for P (40%, 2) for the scaled flow downstream of Taivalkoski
(Kemijoki) is demonstrated in Figure 4. For all the permutations, the
RRR limits peak and minimum hourly flows and ramp rates according to
thresholds defined by the algorithm. Nevertheless, Figure 4.a.
demonstrates that the RRR increases the minimum flow beyond the defined
threshold in numerous time steps without violating other priorities.
However, as illustrated in Figure 4.b., there are time steps where
priority 2 takes precedence over priority 3, causing the ramp rates to
surpass the defined threshold.