Commission Regulation (EU) 2016/631Dangos y teitl llawn

a power-generating module shall be capable of remaining connected to the network and operate within the frequency ranges and time periods specified in Table 2;

the relevant system operator, in coordination with the relevant TSO, and the power-generating facility owner may agree on wider frequency ranges, longer minimum times for operation or specific requirements for combined frequency and voltage deviations to ensure the best use of the technical capabilities of a power-generating module, if it is required to preserve or to restore system security;

the power-generating facility owner shall not unreasonably withhold consent to apply wider frequency ranges or longer minimum times for operation, taking account of their economic and technical feasibility.

continuing operation at this level; or

further decreasing active power output;

each TSO shall specify a voltage-against-time-profile in line with Figure 3 at the connection point for fault conditions, which describes the conditions in which the power-generating module is capable of staying connected to the network and continuing to operate stably after the power system has been disturbed by secured faults on the transmission system;

the voltage-against-time-profile shall express a lower limit of the actual course of the phase-to-phase voltages on the network voltage level at the connection point during a symmetrical fault, as a function of time before, during and after the fault;

the lower limit referred to in point (ii) shall be specified by the relevant TSO using the parameters set out in Figure 3, and within the ranges set out in Tables 3.1 and 3.2;

each TSO shall specify and make publicly available the pre-fault and post-fault conditions for the fault-ride-through capability in terms of:

• the calculation of the pre-fault minimum short circuit capacity at the connection point,

• pre-fault active and reactive power operating point of the power-generating module at the connection point and voltage at the connection point, and

• calculation of the post-fault minimum short circuit capacity at the connection point;

at the request of a power-generating facility owner, the relevant system operator shall provide the pre-fault and post-fault conditions to be considered for fault-ride-through capability as an outcome of the calculations at the connection point as specified in point (iv) regarding:

• pre-fault minimum short circuit capacity at each connection point expressed in MVA,

• pre-fault operating point of the power-generating module expressed in active power output and reactive power output at the connection point and voltage at the connection point, and

• post-fault minimum short circuit capacity at each connection point expressed in MVA.

Alternatively, the relevant system operator may provide generic values derived from typical cases;

Figure 3

Fault-ride-through profile of a power-generating module

The diagram represents the lower limit of a voltage-against-time profile of the voltage at the connection point, expressed as the ratio of its actual value and its reference 1 pu value before, during and after a fault. U_ret is the retained voltage at the connection point during a fault, t_clear is the instant when the fault has been cleared. U_rec1, U_rec2, t_rec1, t_rec2 and t_rec3 specify certain points of lower limits of voltage recovery after fault clearance.

the power-generating module shall be capable of remaining connected to the network and continuing to operate stably when the actual course of the phase-to-phase voltages on the network voltage level at the connection point during a symmetrical fault, given the pre-fault and post-fault conditions in points (iv) and (v) of paragraph 3(a), remain above the lower limit specified in point (ii) of paragraph 3(a), unless the protection scheme for internal electrical faults requires the disconnection of the power-generating module from the network. The protection schemes and settings for internal electrical faults must not jeopardise fault-ride-through performance;

without prejudice to point (vi) of paragraph 3(a), undervoltage protection (either fault-ride-through capability or minimum voltage specified at the connection point voltage) shall be set by the power-generating facility owner according to the widest possible technical capability of the power-generating module, unless the relevant system operator requires narrower settings in accordance with point (b) of paragraph 5. The settings shall be justified by the power-generating facility owner in accordance with this principle;

the schemes and settings of the different control devices of the power-generating module that are necessary for transmission system stability and for taking emergency action shall be coordinated and agreed between the relevant TSO, the relevant system operator and the power-generating facility owner;

any changes to the schemes and settings, mentioned in point (i), of the different control devices of the power-generating module shall be coordinated and agreed between the relevant TSO, the relevant system operator and the power-generating facility owner, in particular if they apply in the circumstances referred to in point (i) of paragraph 5(a);

the relevant system operator shall specify the schemes and settings necessary to protect the network, taking into account the characteristics of the power-generating module. The protection schemes needed for the power-generating module and the network as well as the settings relevant to the power-generating module shall be coordinated and agreed between the relevant system operator and the power-generating facility owner. The protection schemes and settings for internal electrical faults must not jeopardise the performance of a power-generating module, in line with the requirements set out in this Regulation;

electrical protection of the power-generating module shall take precedence over operational controls, taking into account the security of the system and the health and safety of staff and of the public, as well as mitigating any damage to the power-generating module;

protection schemes may cover the following aspects:

• external and internal short circuit,

• asymmetric load (negative phase sequence),

• stator and rotor overload,

• over-/underexcitation,

• over-/undervoltage at the connection point,

• over-/undervoltage at the alternator terminals,

• inter-area oscillations,

• inrush current,

• asynchronous operation (pole slip),

• protection against inadmissible shaft torsions (for example, subsynchronous resonance),

• power-generating module line protection,

• unit transformer protection,

• back-up against protection and switchgear malfunction,

• overfluxing (U/f),

• inverse power,

• rate of change of frequency, and

• neutral voltage displacement.

changes to the protection schemes needed for the power-generating module and the network and to the settings relevant to the power-generating module shall be agreed between the system operator and the power-generating facility owner, and agreement shall be reached before any changes are made;

network and power-generating module protection;

synthetic inertia, if applicable;

frequency control (active power adjustment);

power restriction; and

power gradient constraint;

power-generating facilities shall be capable of exchanging information with the relevant system operator or the relevant TSO in real time or periodically with time stamping, as specified by the relevant system operator or the relevant TSO;

the relevant system operator, in coordination with the relevant TSO, shall specify the content of information exchanges including a precise list of data to be provided by the power-generating facility.

the power-generating module shall be capable of activating the provision of active power frequency response at a frequency threshold and with a droop specified by the relevant TSO in coordination with the TSOs of the same synchronous area as follows:

• the frequency threshold specified by the TSO shall be between [F3349.8] Hz and [F3449.5] Hz inclusive,

• the droop settings specified by the TSO shall be in the range 2-12 %.

This is represented graphically in Figure 4;

the actual delivery of active power frequency response in LFSM-U mode shall take into account:

• ambient conditions when the response is to be triggered,

• the operating conditions of the power-generating module, in particular limitations on operation near maximum capacity at low frequencies and the respective impact of ambient conditions according to paragraphs 4 and 5 of Article 13, and

• the availability of the primary energy sources.

the activation of active power frequency response by the power-generating module shall not be unduly delayed. In the event of any delay greater than two seconds, the power-generating facility owner shall justify it to the relevant TSO;

in LFSM-U mode the power-generating module shall be capable of providing a power increase up to its maximum capacity;

stable operation of the power-generating module during LFSM-U operation shall be ensured;

Figure 4

Active power frequency response capability of power-generating modules in LFSM-U

P_ref is the reference active power to which ΔΡ is related and may be specified differently for synchronous power-generating modules and power park modules. ΔΡ is the change in active power output from the power-generating module. f_n is the nominal frequency (50 Hz) in the network and Δf is the frequency deviation in the network. At underfrequencies where Δf is below Δf₁ the power-generating module has to provide a positive active power output change according to the droop S₂.

the power-generating module shall be capable of providing active power frequency response in accordance with the parameters specified by each relevant TSO within the ranges shown in Table 4. In specifying those parameters, the relevant TSO shall take account of the following facts:

• in case of overfrequency, the active power frequency response is limited by the minimum regulating level,

• in case of underfrequency, the active power frequency response is limited by maximum capacity,

• the actual delivery of active power frequency response depends on the operating and ambient conditions of the power-generating module when this response is triggered, in particular limitations on operation near maximum capacity at low frequencies according to paragraphs 4 and 5 of Article 13 and available primary energy sources;

Table 4

Parameters for active power frequency response in FSM (explanation for Figure 5)

Parameters		Ranges
Active power range related to maximum capacity		[F351.5]-10 %
Frequency response insensitivity		10-30 mHz
		[F360.02]-[F370.06] %
Frequency response deadband		0-500 mHz
Droop s 1		2-12 %

Figure 5

Active power frequency response capability of power-generating modules in FSM illustrating the case of zero deadband and insensitivity

P_ref is the reference active power to which ΔΡ is related. ΔΡ is the change in active power output from the power-generating module. f_n is the nominal frequency (50 Hz) in the network and Δf is the frequency deviation in the network.

the frequency response deadband of frequency deviation and droop must be able to be reselected repeatedly;

in the event of a frequency step change, the power-generating module shall be capable of activating full active power frequency response, at or above the full line shown in Figure 6 in accordance with the parameters specified by each TSO (which shall aim at avoiding active power oscillations for the power-generating module) within the ranges given in Table 5. The combination of choice of the parameters specified by the TSO shall take possible technology-dependent limitations into account;

the initial activation of active power frequency response required shall not be unduly delayed.

If the delay in initial activation of active power frequency response is greater than two seconds, the power-generating facility owner shall provide technical evidence demonstrating why a longer time is needed.

For power-generating modules without inertia, the relevant TSO may specify a shorter time than two seconds. If the power-generating facility owner cannot meet this requirement they shall provide technical evidence demonstrating why a longer time is needed for the initial activation of active power frequency response;

Figure 6

Active power frequency response capability

P_max is the maximum capacity to which ΔΡ relates. ΔΡ is the change in active power output from the power-generating module. The power-generating module has to provide active power output ΔΡ up to the point ΔΡ₁ in accordance with the times t₁ and t₂ with the values of ΔΡ₁, t₁and t₂ being specified by the relevant TSO according to Table 5. t₁ is the initial delay. t₂ is the time for full activation.

the power-generating module shall be capable of providing full active power frequency response for a period of between 15 and 30 minutes as specified by the relevant TSO. In specifying the period, the TSO shall have regard to active power headroom and primary energy source of the power-generating module;

within the time limits laid down in point (v) of paragraph 2(d), active power control must not have any adverse impact on the active power frequency response of power-generating modules;

the parameters specified by the relevant TSO in accordance with points (i), (ii), (iii) and (v) shall be notified to the F38... regulatory authority. The modalities of that notification shall be specified in accordance with the applicable F39... regulatory framework;

Table 5

Parameters for full activation of active power frequency response resulting from frequency step change (explanation for Figure 6)

Parameters	Ranges or values
Active power range related to maximum capacity (frequency response range)	[F401.5]-10 %
For power-generating modules with inertia, the maximum admissible initial delay t 1 unless justified otherwise in line with Article 15(2)(d)(iv)	2 seconds
For power-generating modules without inertia, the maximum admissible initial delay t 1 unless justified otherwise in line with Article 15(2)(d)(iv)	as specified by the relevant TSO.
Maximum admissible choice of full activation time t 2, unless longer activation times are allowed by the relevant TSO for reasons of system stability	30 seconds

to monitor the operation of active power frequency response, the communication interface shall be equipped to transfer in real time and in a secured manner from the power-generating facility to the network control centre of the relevant system operator or the relevant TSO, at the request of the relevant system operator or the relevant TSO, at least the following signals:

• status signal of FSM (on/off),

• scheduled active power output,

• actual value of the active power output,

• actual parameter settings for active power frequency response,

• droop and deadband;

the relevant system operator and the relevant TSO shall specify additional signals to be provided by the power-generating facility by monitoring and recording devices in order to verify the performance of the active power frequency response provision of participating power-generating modules.

black start capability is not mandatory without prejudice to [F41any enactment, licence condition or industry code which confers powers on a person to introduce obligatory requirements] in order to ensure system security;

power-generating facility owners shall, at the request of the relevant TSO, provide a quotation for providing black start capability. The relevant TSO may make such a request if it considers system security to be at risk due to a lack of black start capability in its control area;

a power-generating module with black start capability shall be capable of starting from shutdown without any external electrical energy supply within a time frame specified by the relevant system operator in coordination with the relevant TSO;

a power-generating module with black start capability shall be able to synchronise within the frequency limits laid down in point (a) of Article 13(1) and, where applicable, voltage limits specified by the relevant system operator or in Article 16(2);

a power-generating module with black start capability shall be capable of automatically regulating dips in voltage caused by connection of demand;

a power-generating module with black start capability shall:

• be capable of regulating load connections in block load,

• be capable of operating in LFSM-O and LFSM-U, as specified in point (c) of paragraph 2 and Article 13(2),

• control frequency in case of overfrequency and underfrequency within the whole active power output range between minimum regulating level and maximum capacity as well as at houseload level,

• be capable of parallel operation of a few power-generating modules within one island, and

• control voltage automatically during the system restoration phase;

power-generating modules shall be capable of taking part in island operation if required by the relevant system operator in coordination with the relevant TSO and:

• the frequency limits for island operation shall be those established in accordance with point (a) of Article 13(1),

• the voltage limits for island operation shall be those established in accordance with Article 15(3) or Article 16(2), where applicable;

power-generating modules shall be able to operate in FSM during island operation, as specified in point (d) of paragraph 2.

In the event of a power surplus, power-generating modules shall be capable of reducing the active power output from a previous operating point to any new operating point within the P-Q-capability diagram. In that regard, the power-generating module shall be capable of reducing active power output as much as inherently technically feasible, but to at least 55 % of its maximum capacity;

the method for detecting a change from interconnected system operation to island operation shall be agreed between the power-generating facility owner and the relevant system operator in coordination with the relevant TSO. The agreed method of detection must not rely solely on the system operator's switchgear position signals;

power-generating modules shall be able to operate in LFSM-O and LFSM-U during island operation, as specified in point (c) of paragraph 2 and Article 13(2);

in case of disconnection of the power-generating module from the network, the power-generating module shall be capable of quick re-synchronisation in line with the protection strategy agreed between the relevant system operator in coordination with the relevant TSO and the power-generating facility;

a power-generating module with a minimum re-synchronisation time greater than 15 minutes after its disconnection from any external power supply must be designed to trip to houseload from any operating point in its P-Q-capability diagram. In this case, the identification of houseload operation must not be based solely on the system operator's switchgear position signals;

power-generating modules shall be capable of continuing operation following tripping to houseload, irrespective of any auxiliary connection to the external network. The minimum operation time shall be specified by the relevant system operator in coordination with the relevant TSO, taking into consideration the specific characteristics of prime mover technology.

power-generating facilities shall be equipped with a facility to provide fault recording and monitoring of dynamic system behaviour. This facility shall record the following parameters:

• voltage,

• active power,

• reactive power, and

• frequency.

The relevant system operator shall have the right to specify quality of supply parameters to be complied with on condition that reasonable prior notice is given;

the settings of the fault recording equipment, including triggering criteria and the sampling rates shall be agreed between the power-generating facility owner and the relevant system operator in coordination with the relevant TSO;

the dynamic system behaviour monitoring shall include an oscillation trigger specified by the relevant system operator in coordination with the relevant TSO, with the purpose of detecting poorly damped power oscillations;

the facilities for quality of supply and dynamic system behaviour monitoring shall include arrangements for the power-generating facility owner, and the relevant system operator and the relevant TSO to access the information. The communications protocols for recorded data shall be agreed between the power-generating facility owner, the relevant system operator and the relevant TSO;

at the request of the relevant system operator or the relevant TSO, the power-generating facility owner shall provide simulation models which properly reflect the behaviour of the power-generating module in both steady-state and dynamic simulations (50 Hz component) or in electromagnetic transient simulations.

The power-generating facility owner shall ensure that the models provided have been verified against the results of compliance tests referred to in Chapters 2, 3 and 4 of Title IV, and shall notify the results of the verification to the relevant system operator or relevant TSO. [F42The regulatory authority] may require that such verification be carried out by an authorised certifier;

the models provided by the power-generating facility owner shall contain the following sub-models, depending on the existence of the individual components:

• alternator and prime mover,

• speed and power control,

• voltage control, including, if applicable, power system stabiliser (‘PSS’) function and excitation control system,

• power-generating module protection models, as agreed between the relevant system operator and the power-generating facility owner, and

• converter models for power park modules;

the request by the relevant system operator referred to in point (i) shall be coordinated with the relevant TSO. It shall include:

• the format in which models are to be provided,

• the provision of documentation on a model's structure and block diagrams,

• an estimate of the minimum and maximum short circuit capacity at the connection point, expressed in MVA, as an equivalent of the network;

the power-generating facility owner shall provide recordings of the power-generating module's performance to the relevant system operator or relevant TSO if requested. The relevant system operator or relevant TSO may make such a request, in order to compare the response of the models with those recordings;

without prejudice to point (a) of Article 14(3) and point (a) of paragraph 3 below, a power-generating module shall be capable of staying connected to the network and operating within the ranges of the network voltage at the connection point, expressed by the voltage at the connection point related to the reference 1 pu voltage, and for the time periods specified in Tables 6.1 and 6.2;

the relevant TSO may specify shorter periods of time during which power-generating modules shall be capable of remaining connected to the network in the event of simultaneous overvoltage and underfrequency or simultaneous undervoltage and overfrequency;

F43...

for the 400 kV grid voltage level (or alternatively commonly referred to as 380 kV level), the reference 1 pu value is 400 kV; for other grid voltage levels, the reference 1 pu voltage may differ for each system operator in the same synchronous area;

F44...

power-generating modules shall be capable of staying connected to the network and continuing to operate stably after the power system has been disturbed by secured faults. That capability shall be in accordance with a voltage-against-time profile at the connection point for fault conditions specified by the relevant TSO.

The voltage-against-time-profile shall express a lower limit of the actual course of the phase-to-phase voltages on the network voltage level at the connection point during a symmetrical fault, as a function of time before, during and after the fault.

That lower limit shall be specified by the relevant TSO, using the parameters set out in Figure 3 and within the ranges set out in Tables 7.1 and 7.2 for type D power-generating modules connected at or above the 110 kV level.

That lower limit shall also be specified by the relevant TSO, using parameters set out in Figure 3 and within the ranges set out in Tables 3.1 and 3.2 for type D power-generating modules connected below the 110 kV level;

each TSO shall specify the pre-fault and post-fault conditions for the fault-ride-through capability referred to in point (iv) of Article 14(3)(a). The specified pre-fault and post-fault conditions for the fault-ride-through capability shall be made publicly available;

pre-fault minimum short circuit capacity at each connection point expressed in MVA;

pre-fault operating point of the power-generating module expressed as active power output and reactive power output at the connection point and voltage at the connection point; and

post-fault minimum short circuit capacity at each connection point expressed in MVA;

voltage;

frequency;

phase angle range;

phase sequence;

deviation of voltage and frequency.

the relevant system operator in coordination with the relevant TSO shall specify the reactive power provision capability requirements in the context of varying voltage. For that purpose the relevant system operator shall specify a U-Q/P_max-profile within the boundaries of which the synchronous power-generating module shall be capable of providing reactive power at its maximum capacity. The specified U-Q/P_max profile may take any shape, having regard to the potential costs of delivering the capability to provide reactive power production at high voltages and reactive power consumption at low voltages;

the U-Q/P_max-profile shall be specified by the relevant system operator in coordination with the relevant TSO, in conformity with the following principles:

• the U-Q/P_max-profile shall not exceed the U-Q/P_max-profile envelope, represented by the inner envelope in Figure 7,

• the dimensions of the U-Q/P_max-profile envelope (Q/P_max range and voltage range) shall be within the range specified for each synchronous area in Table 8, and

• the position of the U-Q/P_max-profile envelope shall be within the limits of the fixed outer envelope in Figure 7;

Figure 7F73

U-Q/P_max-profile of a synchronous power-generating module

The diagram represents boundaries of a U-Q/P_max-profile by the voltage at the connection point, expressed by the ratio of its actual value and the reference 1 pu value, against the ratio of the reactive power (Q) and the maximum capacity (P_max). The position, size and shape of the inner envelope are indicative.

the reactive power provision capability requirement applies at the connection point. For profile shapes other than rectangular, the voltage range represents the highest and lowest values. The full reactive power range is therefore not expected to be available across the range of steady-state voltages;

the synchronous power-generating module shall be capable of moving to any operating point within its U-Q/P_max profile in appropriate timescales to target values requested by the relevant system operator;

bandwidth limitation of the output signal to ensure that the highest frequency of response cannot excite torsional oscillations on other power-generating modules connected to the network;

an underexcitation limiter to prevent the AVR from reducing the alternator excitation to a level which would endanger synchronous stability;

an overexcitation limiter to ensure that the alternator excitation is not limited to less than the maximum value that can be achieved whilst ensuring that the synchronous power-generating module is operating within its design limits;

a stator current limiter; and

a PSS function to attenuate power oscillations, if the synchronous power-generating module size is above a value of maximum capacity specified by the relevant TSO.

the power park module shall be capable of activating the supply of fast fault current either by:

• ensuring the supply of the fast fault current at the connection point, or

• measuring voltage deviations at the terminals of the individual units of the power park module and providing a fast fault current at the terminals of these units;

the relevant system operator in coordination with the relevant TSO shall specify:

• how and when a voltage deviation is to be determined as well as the end of the voltage deviation,

• the characteristics of the fast fault current, including the time domain for measuring the voltage deviation and fast fault current, for which current and voltage may be measured differently from the method specified in Article 2,

• the timing and accuracy of the fast fault current, which may include several stages during a fault and after its clearance;

when the post-fault active power recovery begins, based on a voltage criterion;

a maximum allowed time for active power recovery; and

a magnitude and accuracy for active power recovery;

interdependency between fast fault current requirements according to points (b) and (c) of paragraph 2 and active power recovery;

dependence between active power recovery times and duration of voltage deviations;

a specified limit of the maximum allowed time for active power recovery;

adequacy between the level of voltage recovery and the minimum magnitude for active power recovery; and

adequate damping of active power oscillations.

the relevant system operator in coordination with the relevant TSO shall specify the reactive power provision capability requirements in the context of varying voltage. To that end, it shall specify a U-Q/P_max-profile that may take any shape within the boundaries of which the power park module shall be capable of providing reactive power at its maximum capacity;

the U-Q/P_max-profile shall be specified by each relevant system operator in coordination with the relevant TSO in conformity with the following principles:

• the U-Q/P_max-profile shall not exceed the U-Q/P_max-profile envelope, represented by the inner envelope in Figure 8,

• the dimensions of the U-Q/P_max-profile envelope (Q/P_max range and voltage range) shall be within the values specified for each synchronous area in Table 9,

• the position of the U-Q/P_max-profile envelope shall be within the limits of the fixed outer envelope set out in Figure 8, and

• the specified U-Q/P_max profile may take any shape, having regard to the potential costs of delivering the capability to provide reactive power production at high voltages and reactive power consumption at low voltages;

F80Figure 8

U-Q/P_max-profile of a power park module

The diagram represents boundaries of a U-Q/P_max-profile by the voltage at the connection point, expressed by the ratio of its actual value and its reference 1 pu value, against the ratio of the reactive power (Q) and the maximum capacity (P_max). The position, size and shape of the inner envelope are indicative.

the reactive power provision capability requirement applies at the connection point. For profile shapes other than rectangular, the voltage range represents the highest and lowest values. The full reactive power range is therefore not expected to be available across the range of steady-state voltages;

the relevant system operator in coordination with the relevant TSO shall specify the reactive power provision capability requirements and shall specify a P-Q/P_max-profile that may take any shape within the boundaries of which the power park module shall be capable of providing reactive power below maximum capacity;

the P-Q/P_max-profile shall be specified by each relevant system operator in coordination with the relevant TSO, in conformity with the following principles:

• the P-Q/P_max-profile shall not exceed the P-Q/P_max-profile envelope, represented by the inner envelope in Figure 9,

• the Q/P_max range of the P-Q/P_max-profile envelope is specified for each synchronous area in Table 9,

• the active power range of the P-Q/P_max-profile envelope at zero reactive power shall be 1 pu,

• the P-Q/P_max-profile can be of any shape and shall include conditions for reactive power capability at zero active power, and

• the position of the P-Q/P_max-profile envelope shall be within the limits of the fixed outer envelope set out in Figure 9;

when operating at an active power output below maximum capacity (P<P_max), the power park module shall be capable of providing reactive power at any operating point inside its P-Q/P_max-profile, if all units of that power park module which generate power are technically available that is to say they are not out of service due to maintenance or failure, otherwise there may be less reactive power capability, taking into consideration the technical availabilities;

F87Figure 9

P-Q/P_max-profile of a power park module

The diagram represents boundaries of a P-Q/P_max-profile at the connection point by the active power, expressed by the ratio of its actual value and the maximum capacity pu, against the ratio of the reactive power (Q) and the maximum capacity (P_max). The position, size and shape of the inner envelope are indicative.

the power park module shall be capable of moving to any operating point within its P-Q/P_max profile in appropriate timescales to target values requested by the relevant system operator;

the power park module shall be capable of providing reactive power automatically by either voltage control mode, reactive power control mode or power factor control mode;

for the purposes of voltage control mode, the power park module shall be capable of contributing to voltage control at the connection point by provision of reactive power exchange with the network with a setpoint voltage covering [F880.95] to [F891.05] pu in steps no greater than [F900.01] pu, with a slope having a range of at least 2 to 7 % in steps no greater than [F910.5] %. The reactive power output shall be zero when the grid voltage value at the connection point equals the voltage setpoint;

the setpoint may be operated with or without a deadband selectable in a range from zero to ± 5 % of reference 1 pu network voltage in steps no greater than [F920.5] %;

following a step change in voltage, the power park module shall be capable of achieving 90 % of the change in reactive power output within a time t₁ to be specified by the relevant system operator in the range of 1 to 5 seconds, and must settle at the value specified by the slope within a time t₂ to be specified by the relevant system operator in the range of 5 to 60 seconds, with a steady-state reactive tolerance no greater than 5 % of the maximum reactive power. The relevant system operator shall specify the time specifications;

for the purpose of reactive power control mode, the power park module shall be capable of setting the reactive power setpoint anywhere in the reactive power range, specified by point (a) of Article 20(2) and by points (a) and (b) of Article 21(3), with setting steps no greater than 5 MVAr or 5 % (whichever is smaller) of full reactive power, controlling the reactive power at the connection point to an accuracy within plus or minus 5 MVAr or plus or minus 5 % (whichever is smaller) of the full reactive power;

for the purpose of power factor control mode, the power park module shall be capable of controlling the power factor at the connection point within the required reactive power range, specified by the relevant system operator according to point (a) of Article 20(2) or specified by points (a) and (b) of Article 21(3), with a target power factor in steps no greater than [F930.01]. The relevant system operator shall specify the target power factor value, its tolerance and the period of time to achieve the target power factor following a sudden change of active power output. The tolerance of the target power factor shall be expressed through the tolerance of its corresponding reactive power. This reactive power tolerance shall be expressed by either an absolute value or by a percentage of the maximum reactive power of the power park module;

the relevant system operator, in coordination with the relevant TSO and with the power park module owner, shall specify which of the above three reactive power control mode options and associated setpoints is to apply, and what further equipment is needed to make the adjustment of the relevant setpoint operable remotely;