{"id":20856,"date":"2019-01-20T14:43:44","date_gmt":"2019-01-20T14:43:44","guid":{"rendered":"http:\/\/sitepourvtc.com\/?page_id=20856"},"modified":"2023-02-18T07:02:25","modified_gmt":"2023-02-18T07:02:25","slug":"saturated-boiling-bulk-boiling","status":"publish","type":"page","link":"https:\/\/sitepourvtc.com\/nuclear-engineering\/heat-transfer\/boiling-and-condensation\/saturated-boiling-bulk-boiling\/","title":{"rendered":"Saturated Boiling – Bulk Boiling"},"content":{"rendered":"
In saturated boiling<\/strong> (also known as bulk boiling<\/strong>), the temperature of the liquid slightly exceeds the saturation temperature.<\/p>\n

Bulk boiling<\/strong> may occur when system temperature increases or pressure drops to the boiling point. At this point, the bubbles entering the coolant channel will not collapse.<\/p>\n

The bubbles will tend to join together and form bigger steam bubbles. Steam bubbles are then propelled through the liquid by buoyancy forces, eventually escaping from a free surface.<\/div><\/div>\n

\"Saturated<\/a>

<\/span>Boiling and Condesation<\/div>
\n
\"Phase<\/a>
Phase diagram of water.
Source: wikipedia.org CC BY-SA<\/figcaption><\/figure>\n

In preceding chapters, we have discussed convective heat transfer<\/strong><\/a> with a very important assumption, and we have assumed a single-phase convective heat transfer<\/strong> without any phase change. This chapter focuses on convective heat transfer associated with the change in a fluid phase<\/strong>. In particular, we consider processes that can occur at a solid-liquid or solid\u2013vapor interface, namely, boiling<\/strong> (liquid-to-vapor phase change) and condensation<\/strong> (vapor-to-liquid phase change).<\/p>\n

Latent heat effects<\/strong> associated with the phase change are significant for these cases. Latent heat<\/a><\/strong>, also known as the enthalpy of vaporization, is the amount of heat added to or removed from a substance to produce a phase change. This energy breaks down the intermolecular attractive forces and must provide the energy necessary to expand the gas (the p\u0394V work<\/strong>). When latent heat<\/strong> is added, no temperature change occurs.<\/p>\n

\"Latent<\/a>
The heat of vaporization diminishes with increasing pressure while the boiling point increases, and it vanishes completely at a certain point called the critical point.<\/figcaption><\/figure>\n

The enthalpy of vaporization<\/strong> is a function of the pressure at which that transformation takes place.<\/p>\n

Latent heat of vaporization \u2013 water at 0.1 MPa (atmospheric pressure)<\/p>\n

h<\/strong>lg<\/sub><\/strong> = 2257 kJ\/kg<\/strong><\/p>\n

Latent heat of vaporization \u2013 water at 3 MPa<\/p>\n

h<\/strong>lg<\/sub><\/strong> = 1795 kJ\/kg<\/strong><\/p>\n

Latent heat of vaporization \u2013 water at 16 MPa (pressure inside a pressurizer<\/a>)<\/p>\n

h<\/strong>lg<\/sub><\/strong> = 931 kJ\/kg<\/strong><\/p>\n

The heat of vaporization<\/strong> diminishes with increasing pressure while the boiling point<\/a> increases, and it vanishes completely at a certain point called the critical point<\/a>. Above the critical point, the liquid and vapor phases are indistinguishable, and the substance is called a supercritical fluid<\/a>.<\/p>\n

\"supercritical-phase-critical-point-min\"The change from the liquid to the vapor state due to boiling<\/strong> is sustained by heat transfer from the solid surface; conversely, condensation<\/strong> of a vapor to the liquid state results in heat transfer to the solid surface. Boiling and condensation<\/strong> differ from other forms of convection in that they depend on the latent heat of vaporization<\/strong>, which is very high<\/strong> for common pressures<\/a>. Therefore large amounts of heat can be transferred during boiling and condensation essentially at a constant temperature. Heat transfer coefficients<\/a>, h, associated with boiling and condensation<\/strong> are typically much higher<\/strong> than those encountered in other forms of convection processes that involve a single phase.<\/p>\n

This is due to the fact even in a turbulent flow<\/a>. There\u00a0is a stagnant fluid film layer (laminar sublayer) that isolates the surface of the heat exchanger. This stagnant fluid film layer<\/strong> plays a crucial role in the convective heat transfer coefficient. It is observed that the fluid comes to a complete stop at the surface<\/strong> and assumes a zero velocity relative to the surface. This phenomenon is known as the no-slip condition, and therefore, at the surface, <\/strong>energy flow occurs purely by conduction. <\/strong>But in the next layers, both conduction and diffusion-mass movement occur at the molecular or macroscopic levels. Due to the mass movement, the rate of energy transfer is higher. As was written, nucleate boiling<\/strong> at the surface effectively disrupts this stagnant layer. Therefore, nucleate boiling significantly increases the ability of a surface to transfer thermal energy<\/a> to the bulk fluid.<\/div><\/div><\/div>\n

\n

Bulk Boiling in BWRs<\/h2>\n

\"Flow<\/a>In <\/strong>BWRs<\/strong><\/a>, coolant boiling occurs at normal operation<\/strong> and is a very desired phenomenon. Typical flow qualities<\/strong> in BWR cores<\/strong><\/a> are on the order of 10 to 20 %. A boiling water reactor<\/strong> is cooled and moderated<\/a> by water like a PWR, but at a lower pressure<\/strong> (7MPa), which allows the water to boil inside the pressure vessel <\/strong>producing the steam that runs the turbines. Evaporation, therefore, occurs directly in fuel channels. Therefore BWRs are the best example for this area because coolant evaporation occurs at normal operation, and it is a very desired phenomenon.<\/p>\n

In BWRs, there is a phenomenon of the highest importance in reactor safety<\/strong>. This phenomenon is known as the \u201cdry-out\u201d<\/strong> and is directly associated with changes in flow pattern<\/strong> during evaporation in the high-quality region. At normal, the fuel surface is effectively cooled by boiling coolant. However, when the heat flux exceeds a critical value <\/strong>(CHF \u2013 critical heat flux), the flow pattern may reach the dry-out\u00a0conditions<\/strong> (the thin film of liquid disappears). The heat transfer from the fuel surface into the coolant is deteriorated due to a drastically increased fuel surface temperature<\/strong>.<\/p>\n

Bulk Boiling in PWRs<\/h2>\n

For PWRs at normal operation, there is compressed liquid water<\/a> inside the reactor core, loops, and steam generators. The pressure is maintained at approximately 16MPa<\/strong>. At this pressure, water boils at approximately 350\u00b0C<\/strong>(662\u00b0F), which gives a subcooling margin (the difference between the pressurizer temperature and the coolant outlet temperature in the reactor core) of 30 \u00b0C. Noteworthy, this subcooling margin concerns the bulk temperature since bulk boiling is in any case prohibited.<\/p>\n

Subcooling margin is an important safety parameter of PWRs since the bulk boiling in the reactor core must be excluded. The basic design of the pressurized water reactor\u00a0<\/strong>includes such a requirement that the coolant (water) in the reactor coolant system must not boil. To achieve this, the coolant in the reactor coolant system is maintained at a pressure sufficiently high that boiling does not occur at the coolant temperatures experienced while the plant is operating or in an analyzed transient.<\/p>\n

As\u00a0was calculated in the example<\/a>, the surface temperature TZr,1<\/sub> = 325\u00b0C ensures that even subcooled boiling does not occur. Note that subcooled boiling requires TZr,1<\/sub> = Tsat<\/sub>. Since the inlet temperatures of the water are usually about 290\u00b0C<\/strong> (554\u00b0F), it is obvious this example corresponds to the lower part of the core. At higher core elevations, the bulk temperature may reach up to 330\u00b0C. The temperature difference of 29\u00b0C causes the subcooled surface boiling may occur<\/strong> (330\u00b0C + 29\u00b0C > 350\u00b0C). On the other hand, nucleate boiling<\/strong> at the surface effectively disrupts the stagnant layer. Therefore, nucleate boiling significantly increases the ability of a surface to transfer thermal energy<\/a> to the bulk fluid. As a result, the convective heat transfer coefficient significantly increases, and therefore at higher elevations, the temperature difference (TZr,1<\/sub> \u2013 Tbulk<\/sub>) significantly decreases.<\/p>\n

Nucleate Boiling – Flow Boiling<\/h2>\n

\"Flow<\/a>In flow boiling<\/strong> (or forced convection boiling<\/strong>), fluid flow is forced over a surface by external means such as a pump, as well as by buoyancy effects. Therefore, flow boiling is always accompanied by other convection effects. Conditions depend strongly on geometry, involving external flow over heated plates and cylinders or internal (duct) flow. In nuclear reactors, most boiling regimes are just forced convection boiling. The flow boiling is also classified as either external and internal flow boiling, depending on whether the fluid is forced to flow over a heated surface or inside a heated channel.<\/p>\n

Internal flow boiling is much more complicated in nature than external flow boiling because there is no free surface for the vapor to escape, and thus both the liquid and the vapor are forced to flow together. The two-phase flow in a tube exhibits different flow boiling regimes, depending on the relative amounts of the liquid and the vapor phases. Therefore internal forced convection boiling is commonly referred to as two-phase flow<\/strong>.<\/p>\n

Nucleate Boiling Correlations – Flow Boiling<\/h2>\n

McAdams Correlation<\/h3>\n

In fully developed nucleate boiling with saturated coolant, the wall temperature is determined by local heat flux and pressure and is only slightly dependent on the Reynolds number<\/a>. For subcooled water at absolute pressures between 0.1 – 0.6 MPa, McAdams correlation<\/strong> gives:<\/p>\n

\"nucleate<\/a><\/p>\n

Thom Correlation<\/h3>\n

The Thom correlation<\/strong> is for the flow boiling (subcooled or saturated at pressures up to about 20 MPa) under conditions where the nucleate boiling contribution predominates over forced convection. This correlation is useful for a rough estimation of expected temperature difference given the heat flux:<\/p>\n

\"nucleate<\/a><\/p>\n

Chen\u2019s Correlation<\/h3>\n

In 1963, Chen<\/strong> proposed the first flow boiling correlation for evaporation in vertical tubes to attain widespread use. Chen\u2019s correlation<\/strong> includes both the heat transfer coefficients<\/a> due to nucleate boiling<\/strong> as well as forced convective mechanisms<\/strong>. It must be noted at higher vapor fractions. The heat transfer coefficient varies strongly with the flow rate, and the flow velocity in a core can be very high, causing very high turbulences. This heat transfer mechanism has been referred to as \u201cforced convection evaporation\u201d. No adequate criteria have been established to determine the transition from nucleate boiling to forced convection vaporization. However, a single correlation that is valid for both nucleate boiling and forced convection vaporization has been developed by Chen for saturated boiling conditions and extended to include subcooled boiling by others. Chen proposed a correlation where the heat transfer coefficient is the sum<\/strong> of a forced convection<\/strong> component and a nucleate boiling<\/strong> component. It must be noted the nucleate pool boiling correlation of Forster and Zuber (1955) is used to calculate the nucleate boiling heat transfer coefficient, hFZ<\/sub>, and the turbulent flow correlation of Dittus-Boelter (1930) is used to calculate the liquid-phase convective heat transfer coefficient, hl<\/sub>.<\/p>\n

\"Chens<\/a><\/p>\n

The nucleate boiling suppression factor, S, is the ratio of the effective superheats to wall superheat. It accounts for decreased boiling heat transfer because the effective superheat across the boundary layer is less than the superheat based on wall temperature. The two-phase multiplier, F, is a function of the Martinelli parameter \u03c7tt<\/sub>.<\/p>\n<\/div>\n

<\/div>\n
\u00a0
<\/span>References:<\/div>
Heat Transfer:<\/strong>\n
    \n
  1. Fundamentals of Heat and Mass Transfer, 7th Edition. Theodore L. Bergman, Adrienne S. Lavine, Frank P. Incropera. John Wiley & Sons, Incorporated, 2011. ISBN: 9781118137253.<\/li>\n
  2. Heat and Mass Transfer. Yunus A. Cengel. McGraw-Hill Education, 2011. ISBN: 9780071077866.<\/li>\n
  3. U.S. Department of Energy, Thermodynamics, Heat Transfer and Fluid Flow. DOE Fundamentals Handbook, Volume 2 of 3. May 2016.<\/li>\n<\/ol>\n

    Nuclear and Reactor Physics:<\/strong><\/p>\n

      \n
    1. J. R. Lamarsh, Introduction to Nuclear Reactor Theory, 2nd ed., Addison-Wesley, Reading,\u00a0MA (1983).<\/li>\n
    2. J. R. Lamarsh, A. J. Baratta, Introduction to Nuclear Engineering, 3d ed., Prentice-Hall, 2001, ISBN: 0-201-82498-1.<\/li>\n
    3. W. M. Stacey, Nuclear Reactor Physics, John Wiley & Sons, 2001, ISBN: 0- 471-39127-1.<\/li>\n
    4. Glasstone, Sesonske. Nuclear Reactor Engineering: Reactor Systems Engineering,\u00a0Springer; 4th edition, 1994, ISBN:\u00a0978-0412985317<\/li>\n
    5. W.S.C. Williams. Nuclear and Particle Physics. Clarendon Press; 1 edition, 1991, ISBN: 978-0198520467<\/li>\n
    6. G.R.Keepin. Physics of Nuclear Kinetics. Addison-Wesley Pub. Co; 1st edition, 1965<\/li>\n
    7. Robert Reed Burn, Introduction to Nuclear Reactor Operation, 1988.<\/li>\n
    8. U.S. Department of Energy, Nuclear Physics and Reactor Theory. DOE Fundamentals Handbook, Volume 1 and 2. January 1993.<\/li>\n
    9. Paul Reuss, Neutron Physics. EDP Sciences, 2008. ISBN: 978-2759800414.<\/li>\n<\/ol>\n

      <\/strong>Advanced Reactor Physics:<\/strong><\/p>\n

        \n
      1. K. O. Ott, W. A. Bezella, Introductory Nuclear Reactor Statics, American Nuclear Society, Revised edition (1989), 1989, ISBN: 0-894-48033-2.<\/li>\n
      2. K. O. Ott, R. J. Neuhold, Introductory Nuclear Reactor Dynamics, American Nuclear Society, 1985, ISBN: 0-894-48029-4.<\/li>\n
      3. D. L. Hetrick, Dynamics of Nuclear Reactors, American Nuclear Society, 1993, ISBN: 0-894-48453-2.<\/li>\n
      4. E. E. Lewis, W. F. Miller, Computational Methods of Neutron Transport, American Nuclear Society, 1993, ISBN: 0-894-48452-4.<\/li>\n<\/ol>\n<\/div><\/div><\/div>
        <\/div><\/div><\/div>
        <\/div>
        <\/div><\/div>
        \n

        See above:<\/h2>\n

        Boiling and Condensation<\/i> <\/span><\/a><\/p><\/div><\/div>