The schematic of energy conservation in the model is shown in Figure 1. Assuming that the flow is gas-liquid two-phase flow, the energy equation of wellbore unsteady flow and heat transfer is proposed. The annular element of the well section below the mudline is analyzed as follows.

① The heat flowing into the micro element from the lower end face Q A ( s + d s )

Each parameter is a function of time and position, T a = T a ( s , t ) , m i = m i ( s , t ) , C i = C i ( s , t ) . As shown in Figure 1, the temperature at the lower surface is T a + ∂ T a ∂ s d s , and each parameter is ∑ [ ( m i C i ) + ∂ ( m i C i ) ∂ s d s ] Q A ( s + d s ) = ∑ [ ( m i C i ) + ∂ ( m i C i ) ∂ s d s ] ( T a + ∂ T a ∂ s d s ) (6) Where, i is each component in the wellbore, respectively, g (gas), w (drilling fluid), C (rock cuttings) and H (hydrate); m _i is the mass flow rate of each component, kg/s; C _i is the specific heat capacity of each component, J/(kg^. °C).

② The heat flowing into the micro element from the lower end face Q A ( s )

The temperature at the upper end is T a , Q A ( s ) = ∑ ( m i C i ) T a (7)

③ Heat flowing from the formation into the annulus Q E → A

In which, U A is the total heat transfer coefficient between annulus fluid and formation, which is related to the thermal resistance of annulus fluid, casing and cement sheath. Generally, the thermal resistance of steel is small, and the temperature of inner and outer walls of casing can be approximately equal, 1 U A = 1 h a + r c i ln ( r c o / r c i ) k c + r c o ln ( r w b / r c o ) k c e (10)

T_D is the transient heat transfer function, which is simulated as follows T D = 1.128 t D ( 1 − 0.3 t D )   10 − 10 ≤ t D ≤ 1.5 (11) T D = [ 0.4036 + 0.5 ln ( t D ) ] ( 1 + 0.6 t D )   t D ≥ 1.5 (12) t D = k e t C e ρ e r w b 2 (13)

In case of the seawater section, 1 U A = 1 h a + r c i ln ( r r s o / r r s i ) k r s (14) Where, k _rs is the thermal conductivity of riser.

④ Heat flowing into the drilling tool from the annulus Q A → D P

According to the energy conservation, the heat change inside the unit body = the heat flowing into the unit body—the heat flowing out of the unit body, i.e. d Q = Q A ( s + d s ) − Q A ( s ) + Q E → A − Q A → D P (19) ∂ ∂ t ∑ ( ρ i E i C i A ) T a d s = ∑ [ ( m i C i ) + ∂ ( m i C i ) ∂ s d s ] ( T a + ∂ T a ∂ s d s ) − ∑ ( m i C i ) T a + 1 α ( T E − T a ) d s − 1 β A ( T a − T D P ) d s (20)

Since ∑ [ ∂ ( m i C i ) ∂ s d s ] ( ∂ T a ∂ s d s ) = 0 , we obtain ∂ ∂ t ∑ ( ρ i E i C i A ) T a d s = ∑ [ ( m i C i ) ] ( ∂ T a ∂ s d s ) + ∑ [ ∂ ( m i C i ) ∂ s d s ] ( T a ) + ∑ [ ∂ ( m i C i ) ∂ s d s ] ( ∂ T a ∂ s d s ) + 1 α ( T E − T a ) d s − 1 β A ( T a − T D P ) d s ≈ ∑ [ ∂ ( m i C i T a ) ∂ s d s ] + 1 α ( T E − T a ) d s − 1 β A ( T a − T D P ) d s (21)

Therefore, the temperature field equation in the annulus is obtained as, ∂ ∂ t ∑ ( ρ i E i C i A ) T a = ∑ [ ∂ ∑ ( m i C i T a ) ∂ s ] + 1 α ( T E − T a ) − 1 β A ( T a − T D P ) (22)

Similarly, the equation of temperature field in drill pipe is obtained as, ∂ ( ρ w C w A T p ) ∂ t + ∂ ( C w m w T p ) ∂ s = 2 β A ( T a − T D P ) (23)

1) Seawater temperature field.

The complex ambient temperature field is one of the key factors affecting the multiphase flow rules in wellbore. The temperature at seawater section decreases gradually with water depth, and the variation trend is nonlinear. However, the temperature at formation rock section gradually increases with well depth, and the change trend is related to the formation temperature gradient.

The simulation methods of seawater temperature in spring, summer and autumn (Gao, 2007 [30]) are as follows.

① Water depth h ≤ 200 m,

2) Formation temperature field.

The variation of formation temperature field in deep-water drilling is similar to that in onshore drilling. The formation temperature gradient is mainly related to the lithology and sedimentary characteristics of the rocks. T E ( h ) = T 0 + ∫ h 0 h ∆ T   d L (32) Where, T ₀ is seawater temperature at mudline, °C; h ₀ is the sea water depth, m; h is the vertical depth, m.

1) Initial conditions of temperature field

① Start circulating

At initial condition, the fluid temperature in the wellbore is the same as the ambient temperature: T p = T a = T E (33)

② Gas kick process

The initial condition of temperature field in gas kick is the temperature distribution of drill pipe and annulus calculated at the moment before gas kick.

2) Initial conditions of pressure field

During normal drilling, there is no gas influx E H ( s , 0 ) = E g ( s , 0 ) = 0 (34) E c ( s , 0 ) = E g ( s , 0 ) C c V s l ( s , 0 ) + V c r ( s , 0 ) (35) E w ( s , 0 ) = 1 − E c ( s , 0 ) (36) V s w ( s , 0 ) = Q m A ( s ) (37) V w ( s , 0 ) = V s w ( s , 0 ) E w ( s , 0 ) (38) V s c ( s , 0 ) = q c ρ c A ( s ) (39) V c ( s , 0 ) = V s c ( s , 0 ) E c ( s , 0 ) (40) P ( s , 0 ) = P ( s ) (41) Where, Q _m is the displacement of mud pump, m³/s; q _c is the displacement of rock cuttings, m³/s.

Regarding the calculation of flow parameters during pump shutdown and well killing, the initial conditions are the distribution of flow parameters in the wellbore at the moment before the change of working conditions.

1) Boundary conditions of temperature field

Because the liquid temperature at the drill string inlet can be measured directly, the boundary condition of the temperature field is T p ( 0 , t ) = T i n (42)

At the same time, the temperatures of the liquid in the drill string and the annulus liquid at the bottom of the well are equal, i.e. T p ( H , t ) = T a ( H , t ) (43) Where, T _in is the inlet temperature of drill string, °C; T _in is the well depth, m.

2) Boundary conditions of pressure field and velocity field

During a gas kick, the boundary conditions of pressure and flow velocity parameters are as follows. P ( 0 , t ) = P s (44) q g ( H , t ) = q g (45) q c ( H , t ) = q c (46) r H ( i , t ) = r H (47) Where, P _s is wellhead back pressure, Pa.

It is very difficult to obtain the analytical solution directly for the established multiphase flow model. In this study, the corresponding numerical algorithm is established for the above model. Firstly, the wellbore needs to be meshed, and the spatial grid length (usually long at the bottom and short at the top) is dynamically selected according to the fluid velocity and gas rising velocity in the wellbore. Then set the initial time step, and automatically adjust the time step according to the calculation speed requirements.

According to the gas rising speed v g , average fluid velocity v m , and the time step ∆ t j , the time step is determined as ∆ S j = ∆ t j | U | C 0 (48) Where, ∆t _j is the time step of node j, s; ∆S _j is the spatial step of node j, m; |U| is the absolute value of the correlation speed at node j, U = min ⁡ ⁡ ( v g , v m ) ; C 0 is the Courant number. In order to achieve the accuracy and stability of calculation, C 0 < 1 。

The schematic diagram of spatial grid division is shown in Figure 2. The length of any spatial grid is ∆ S j = S j + 1 − D j . Theoretically, because the velocity in the drill pipe is greater than that in the annulus, in order to speed up the calculation. The spatial grid step in the drill pipe should be greater than that in the annulus at the same position. However, for facilitating the coupling calculation between drill pipe and annulus and ensure the calculation accuracy, the spatial grid in drill pipe is the same as that in annulus.

The dynamic grid difference model are used in this study. Taking the gas phase continuity equation as an example, the CV discrete method (control volume method) is adopted, ∂ ( E g A ρ g ) ∂ t + ∂ ∂ s ( ρ g v g E g A + R g ρ g V w E w A ) = q g + x g r H (49)

The schematic of spatial grid division is shown in Figure 3. Where, E represents i + 1 node, W represents i − 1 node, P represents i node, e represents i + 1 / 2 node, and w represents i − 1 / 2 node.

Eq. 49 can be differenced as follows: ∫ ∂ ∂ t ( E g A ρ g ) d V ≈ [ ( E g A ρ g ) P − ( E g A ρ g ) P 0 ] ∆ V ∆ T (50) ∫ ∂ ∂ s ( ρ g v g E g A + R g ρ g V w E w A ) d V ≈ [ ξ e ( ρ g v g E g A + R g ρ g V w E w A ) E + ξ ¯ e ( ρ g v g E g A + R g ρ g V w E w A ) P ] A e − [ ξ w ( ρ g v g E g A + R g ρ g V w E w A ) P + ξ ¯ e ( ρ g v g E g A + R g ρ g V w E w A ) W ] A w (51) ∫ R ϕ d V ≈ R ¯ ϕ ∆ V − R ϕ ′ ϕ P ∆ V   R ϕ = R q g + x g r H (52) Where, ξ and ξ ′ is the convection difference weight factor. The difference form of the continuity equation of gas phase is [ ( E g A ρ g ) P − ( E g A ρ g ) P 0 ] ∆ V ∆ T + { [ ξ e ( ρ g v g E g A + R g ρ g V w E w A ) E + ξ ¯ e ( ρ g v g E g A + R g ρ g V w E w A ) P ] A e − [ ξ w ( ρ g v g E g A + R g ρ g V w E w A ) P + ξ ¯ w ( ρ g v g E g A + R g ρ g V w E w A ) W ] A w } = R ¯ ϕ ∆ V − R ϕ ′ ϕ P ∆ V (53)

Similarly, the momentum equation and energy equation of wellbore multiphase flow model can be obtained and solved [29].