Term
| Purpose of C.5-1200 (Primary Containment Control) |
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Definition
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Term
| Five key parameters controlled in C.5-1200 (Primary Containment Control) |
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Definition
Combustible gas concentration (H2): 2% Torus Temp: 90o F Torus water level: below -4" or above +3" Drywell Temp: 135o F Primary containment pressure: 2 psig (NOTE: scram setpoint is 1.84 psig. However, EOP entry is still 2 psig as of ILT '09
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Term
| Definition of Adequate Core Cooling |
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Definition
Preventing fuel clad rupture by (in order of preference): |
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Term
| Preferred method of core cooling |
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Definition
| Submergence (water level above top of active fuel, which is -126 inches) |
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Term
| Entry points for C.5-1200 (Primary Containment Control) |
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Definition
DW or torus hydrogen above 2% Torus Temp above 90 degrees F Torus level below -4.0 inches or above +3.0 inches DW temp above 135 degrees F DW pressure above 2 psig
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Term
| Peak clad temperature limit using steam cooling with makeup water |
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Definition
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Term
| The only practical mechanism for containment cooling |
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Definition
| RHR flow through the heat exchanger with RHRSW in service. (Therefore, drywell and Torus spray also counts) |
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Term
| Alternate methods of determining reactor power when power is unknown |
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Definition
| Reactor period, steam flow, RPV Pressure, SRV valve position, torus heatup rate |
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Term
| The greatest banked rod position which the reactor will remain shutdown under all conditions |
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Definition
Maximum Subcritical Banked Withdrawal Position: (for Monticello: position 04 or less.) |
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Term
| Other ways to determine if reactor will remain shutdown |
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Definition
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Term
| Primary objective of C.5-1100 Level Branch |
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Definition
| Keep core submerged and thus adequately cooled. |
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Term
| [This] terminates any loss of reactor coolant through a break. |
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Definition
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Term
| [This] ensures that emergency injection sources are available. |
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Definition
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Term
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Definition
| All pumps, valves, and aux equipment are properly lined up for existing plant conditions; a given system may or may not be injecting. |
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Term
| Reasons ADS actuation is prevented (inhibited) |
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Definition
ADS actuation can imposed a severe thermal transient on the RPV and may complicate efforts to control RPV level If only steam-driven systems are available for injection, ADS actuation may directly lead to loss of adequate core cooling and subsequent core damage The conditions assumed in the design of the ADS actuation logic (e.g., no operator action for 10 minutes after event initiation) may not exist when the actions specified in RPV Control are being carried out The operator can draw on much more information than is available to the ADS logic and can better judge...
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Term
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Definition
| 2% (also, EOP entry condition) |
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Term
| Drywell pressure limit is defined to be the lesser of: |
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Definition
Pressure capability of primary containment The maximum primary containment pressure at which vent valves sized to reject all decay heat from the primary containment can be opened and closed The maximum primary containment pressure at which ADS valves can be opened and will remain open
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Term
| Possible sources of hydrogen |
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Definition
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Term
| List some adverse effects of high torus temperature |
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Definition
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Term
| Torus Temperature EOP entry condition |
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Definition
| 90 degrees (also a Tech Spec limit when no testing to add heat to the Torus. Applicability: MODE 1,2,3) |
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Term
| Torus Level EOP entry condition |
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Definition
| Above +3.0 inches or below -4.0 inches |
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Term
| State the adverse effects of EOP torus level conditions. |
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Definition
High water levels result in higher stresses on primary containment structural components during a LOCA or SRV actuation. Low water levels may result in reduced capacity for condensing steam, loss of ECCS pump NPSH, and vortex formation at ECCS pump suction inlets. |
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Term
| Drywell temperature EOP entry condition |
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Definition
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Term
| Drywell pressure EOP entry condition |
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Definition
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Term
| C.5-1200 statement about drywell pressure entry condition |
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Definition
| A high drywell pressure is a symptom of a break in the drywell, and thus of events which may jeopardize adequate core cooling |
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Term
| C.5-1200 statement about the importance of individual EOP steps |
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Definition
| The symptom-oriented structure of EOPs precludes any advance definition of relative priorities of the individual branches. Rather, the importance of individual steps and the priority with which they should be performed must be judged based on observed parameter values and trends, the availability of plant systems, and an overall assessment of plant conditions. |
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Term
| Action required and reason when Hydrogen concentration reaches 4% in drywell or torus |
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Definition
| Entry into SAMG's because this is indication that adequate core cooling has been lost. |
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Term
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Definition
The highest torus temperature which provides adequate net positive suction head for pumps taking suction from Torus. NOTE: only applies to RCIC and HPCI when suction aligned to Torus. |
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Term
| Define the ECCS Vortex Limit |
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Definition
| Lowest torus water level at which air entrainment is not expected to occur in the suction of pumps aligned to the torus. |
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Term
| In C.5-1200, is RHR NPSH and vortex limits a caution or THE LIMIT? |
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Definition
| A CAUTION to provide necessary event-specific flexibility and to avoid potential conflicts between parallel parameter control paths |
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Term
| Temperature before which a scram is inserted and C.5-1100 is entered. Why? |
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Definition
110 degrees F. The scram reduces the rate of energy production and thus the heat input to the torus If torus temperature continues to rise, a blowdown will be required. The reactor should be scrammed before the blowdown is performed Monticello Tech Specs require a reactor scram (Place the MODE switch in SHUTDOWN) if torus temperature reaches 110 degrees F
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Term
| Why is the torus temperature scram prescribed indirectly through C.5-1100? |
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Definition
C.5-1100 coordinates control of RPV water level and pressure following a scram It also branches to C.5-2007 (Failure to Scram) if all rods are not inserted by the scram An override in the Pressure branch of C.5-1100 allows rapid depressurization through the main turbine bypass valves in anticipation of a possible blowdown
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Term
| Concerning the torus temperature scram of C.5-1200, what is required if C.5-1100 has been entered some time earlier? |
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Definition
| Nothing. A scram has already been initiated then and C.5-1100 need not be re-entered. However, one of the reasons for prescribing a scram through C.5-1100 is anticipating blowdown. |
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Term
| What is significant about the torus temperature of 110 degrees F? |
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Definition
| It is the temperature at which Tech Specs requires a scram and the bounding value of the Boron Injection Initiation Temperature. |
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Term
| Define the heat capacity limit |
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Definition
The highest torus temperature at which a blowdown will not result in exceeding either: while the rate of energy transfer from the RPV to the primary containment is greater than the containment vent capacity. |
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Term
| If torus temperature cannot be held below the Heat Capacity Limit, what must happen? |
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Definition
A blowdown must be performed to preclude: |
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Term
| Discuss Maximum Pressure Suppression Primary Containment Water Level |
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Definition
| The highest torus water level at which pressure suppression capability sufficient to accommodate emergency depressurization and RPV breach by core debris can be maintained. For Mark I containments, this is defined to be the bottom of the vent header, or +3.7 FEET." |
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Term
| Define the SRV Tail Pipe Level Limit |
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Definition
The lower of: The maximum pressure suppression primary containment water level, and The highest torus water level at which opening an SRV will not result in exceeding the code of allowable stresses in the SRV tail pipe, tail pipe supports, quencher, or quencher supports.
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Term
| Discuss the consequences of SRV operation with torus water level above the SRV Tail Pipe Limit |
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Definition
| This could damage the SRV discharge lines. This, in turn, could lead to containment failure from direct pressurization and damage to equipment inside the containment from pipe-whip and jet-impingement loads. |
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Term
| State the torus level associated with the torus-to-drywell vacuum breakers and the significance of this level |
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Definition
4.2 feet. If torus level exceeds this elevation, the vacuum breakers may not function as designed to relieve noncondensibles into the drywell and equalize drywell and torus pressures.
Therefore, drywell spray is permitted only if torus water level is below 4.2 feet and the sprays must be secured if torus level may exceed the limiting elevation. |
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Term
| When is MO-2373 opened? Why? |
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Definition
| Opening the inboard main steam line drain valve (MO-2373) before its motor operator is flooded preserves the main steam line drains for future use. Since primary containment water level cannot be measured at the elevation of concern, the drain valve is opened if it is determined that torus water level cannot be maintained below the elevation of the vacuum breakers (+4.2 feet). |
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Term
| State the torus level associated with the downcomers and the significance of this level. |
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Definition
| Torus level must be maintained above the bottom of the downcomers (-3.3 feet) to ensure that steam discharged from the drywell into the torus following a primary system break will be adequately condensed. If a primary system break were to occur with torus level below -3.3 feet, pressure suppression capability would be unavailable and primary containment pressure could exceed structural limits. |
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Term
| State the torus level associated with HPCI exhaust and the significance of this level. |
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Definition
-3.7 feet If not maintained above this level, HPCI must be secured to prevent direct pressurization of the torus. THIS ACTION IS TAKEN IRRESPECTIVE OF WHETHER THE CORE WILL REMAIN ADEQUATELY COOLED, SINCE FAILURE TO DO SO COULD LEAD TO A COMPLETE AND UNCONTROLLED LOSS OF PRIMARY CONTAINMENT INTEGRITY. This could result in a loss of core cooling and release of substantial amounts of radioactivity to the environment." |
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Term
| What is the RCIC exhaust torus water level limit? |
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Definition
| Trick question. There is no limit. RCIC exhaust flow rate is much smaller and elevated torus pressure will trip the RCIC turbine (exhaust pressure of 50 psig for 5 seconds or 125 psig instantaneous) before primary containment integrity is challenged. |
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Term
| When is operating all available drywell cooling required? Would this include defeating ECCS initiation trips? How about ECCS Load-shed trips? |
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Definition
| Operating 'all available' cooling includes starting any fans not operating and maximizing cooling water flow. ECCS initiation trips may be defeated but ECCS load-shed trips may not?? be defeated. |
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Term
| Drywell design temperature |
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Definition
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Term
| What is ultimately required if drywell temperature cannot be maintained below design temperature? What two actions are addressed prior to this ultimate action? |
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Definition
| Drywell design temperature: 281 degrees F. Ultimately, a blowdown will be required. Prior to this, drywell sprays and a reactor scram are addressed. |
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Term
| Assumptions in the design bases concerning drywell sprays |
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Definition
Design bases assumes use of DW spray at 10 minutes after the break to limit DW temperatures. NOTE: small and intermediate steam line breaks will result in DW temperatures above 281 degrees F. |
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Term
| Definition of Drywell Spray limit |
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Definition
The highest temperature at which initiation of drywell sprays will not result in an evaporative cooling pressure drop to below the high drywell pressure scram setpoint. The goal is avoiding the Drywell EXTERNAL limit of 2 psig |
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Term
| What is the consequence of starting drywell sprays with temperature above the drywell spray limit? |
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Definition
De-inertion of the primary containment or loss of primary containment integrity. Loss of primary containment integrity would be due to exceeding the EXTERNAL pressure limit for primary containment. At temperatures above the drywell spray limit, the containment pressure drop may be too rapid to control/prevent. |
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Term
| If drywell temperature cannot be determined, what assures the operator that the DW spray limit is not exceeded? |
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Definition
The core has remained covered. Dry or superheated steam is needed to exceed the DW spray limit. If the core has remained covered, steam leaving the RPV will remain saturated Drywell pressure is above 14 psig. The DW spray limit is independent of DW temperature above this pressure; The Mollier Diagram indicates isentropic expansion will result in a steam temperature within the DW spray limit.
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Term
| What is the upper limit on torus level for which drywell spray is permitted? |
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Definition
4.2 feet. If torus level exceeds this elevation, the vacuum breakers may not function as designed to relieve noncondensibles into the drywell and equalize drywell and torus pressures. Therefore, drywell spray is permitted only if torus water level is below 4.2 feet |
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Term
| What action is required prior to placing DW spray in operation? |
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Definition
Verify recirc pumps tripped and place DW cooling FAN CONTROL switches in OFF. This is because recirc pumps and DW fans are not qualified for continuous operation in a spray environment. |
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Term
| Can emergency depressurization (Blow Down) be delayed? |
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Definition
NOT RECOMMENDED Yes. May be delayed until DW temperature approaches the max temperature at which ADS is qualified (335 degrees F) or drywell structural integrity is challenged by an adverse trend in drywell airspace temperature. |
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Term
| Before what condition shall torus spray be placed in service? By when is it secured? |
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Definition
Before DRYWELL PRESSURE reaches 12 psig: initiate torus spray. Secure before torus pressure drops to 0 psig. Also, secure DW sprays before DW pressure reaches 0 psig. |
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Term
| What is the basis for initiating drywell sprays at 12 psig? |
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Definition
| To preclude a phenomenon known as chugging (the cyclic condensation of steam at the downcomer openings of the drywell vents). |
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Term
| Define Boron Injection Initiation Temperature |
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Definition
| At Monticello, a fixed torus temperature value of 110 degrees F has been established. In an ATWS SBLC shall be initiated prior to torus reaching 110 degrees F |
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Term
| What is pressure suppression pressure? |
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Definition
| A function of torus level. It is used to ensure that pressure suppression capability sufficient to accommodate emergency RPV depressurization is maintained while the RPV is at pressure. In other words, Blowdown is required prior to violating figure O because the capability of the torus to suppress the energy in the Drywell (DW pressure) is being challenged. |
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Term
| Before starting DW sprays, what things should be considered? |
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Definition
The rate of change of DW temperature rise The margin to 281 degrees F The likelihood of reversing the DW temperature trend before 335 degrees F (ADS qual temp) or challenging the 281 degrees F DW structural limit and, The nature of the prescribed actions, i.e. drywell sprays.
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Term
| Considerations and/or reasons for securing Drywell sprays |
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Definition
Reducing containment pressure below the scram setpoint will clear scram logic and maximize the margin to containment limits If containment has failed or if primary containment venting is anticipated, it may be advisable to continue spray operation at low pressures to scrub the containment atmosphere Reducing primary containment pressure will also reduce NPSH available for pumps drawing suction from the supression pool. If there is no need for continued spray operation, sprays may be terminated at higher pressures to avoid exceeding the NPSH limits.
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Term
Concerning pump operation beyond NPSH and Vortex Limits, what factors should be considered? |
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Definition
Availability of other systems Current trend of plant parameters Anticipated time that such operation will be required Degree to which the limit will be exceeded Sensitivity of the system to operation beyond the limit Consequences of NOT operating a system beyond the limit
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Term
Considerations of whether or not drywell temperature can be restored and maintained below 281 degrees F. |
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Definition
Energy being added to the drywell cannot be significantly reduced Energy being removed from the drywell cannot be significantly increased Drywell temperature is rising and will reach 335 degrees F (max ADS qual temp) within a short time or the structural integrity of primary containment will be challenged.
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Term
Purpose of performing blowdown |
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Definition
| To limit further release of energy into the drywell, thus minimizing the drywell heatup. |
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Term
| If primary containment pressure cannot be maintained below ____ psig with SBGT, pressure may be controlled using _____________. |
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Definition
2 psig Drywell and Torus sprays Spray operation reduces primary containment pressure by condensing any steam present and absorbing heat from containment atmosphere. |
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Term
| Drywell sprays may be initiated only if: |
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Definition
Drywell temperature is below the DW Spray Limit, and Torus water level is below 4.2 feet NOTE: the drywell spray limit is technically defined as the highest temperature at which initiation of drywell sprays will not result in an evaporative cooling pressure drop to below the high drywell pressure scram setpoint. |
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Term
| Discuss single drywell spray loop vs. two loops. |
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Definition
| A single drywell spray loop should normally provide sufficient flow to control drywell temperature and presure and prevent chugging, but both loops may be used if desired. Due to drywell-to-torus vacuum breaker sizing issues, however, the second loop should not be placed in service until after the first loop is actually injecting spray into the drywell. It is expected that operation of both loops will have little effect upon the magnitude or rate of evaporative cooling, but could increase the convective cooling rate. |
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Term
BEFORE DW pressure reaches 12 psig, what must be done? |
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Definition
| Start torus sprays. If drywell pressure can be restored and maintained below 12 psig with torus sprays, drywell sprays need not be initiated. This is important because Drywell sprays may threaten electrical equipment in the drywell and complicate plant recovery. |
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Term
| Will torus spray prevent chugging? |
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Definition
| No. but it can be effective in reducing primary containment pressure, particularly if steam is bypassing the suppression pool and being discharged directly to the torus air space. |
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Term
At what level does torus spray become ineffective? |
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Definition
14.1 feet This is the elevation of the torus spray nozzles. Torus spray will not be effective with level beyond 14.1 feet. |
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Term
| What is the intent of venting primary containment in C.5-1200? |
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Definition
To reduce and maintain pressure below Figure D, DW Pressure Limit. Venting is NOT intended to provide complete relief of primary containment pressure. The preferred vent path is through the torus so the containment atmosphere is scrubbed by the suppression pool. Futhermore, if radiation levels inside primary containment are significant, venting through SBGT is preferred. |
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Term
Preferred path for venting primary containment |
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Definition
| Through the torus so that the containment atmosphere is scrubbed by the suppression pool. Furthermore, if radiation levels inside primary containment are significant, venting through SBGT is preferred. |
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Term
Which is more important: venting primary containment or not exceeding normal offsite release limits? |
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Definition
| The potential importance of primary containment venting warrants exceeding normal offsite release limits and defeating any isolations that interfere with the vent lineups. The consequences of not venting could include loss of primary containment integrity resulting in an uncontrolled radioactivity release MUCH GREATER than might occur otherwise. |
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