MECHANICS CALCULATION METHOD OF DRILL BIT TOOTH CONSIDERING ROCK DYNAMIC STRENGTH AND MIXED CRUSHING MODE

Abstract

The invention discloses a mechanics calculation method of drill bit tooth considering rock dynamic strength and mixed crushing mode, including: Step S1: selecting a target drill bit tooth and a target rock, and determining a type of target drill bit tooth, a geometry of the target drill bit tooth, a rock type and rock parameters of the target rock; Step S2: calculating a horizontal cutting force of the target drill bit tooth according to a horizontal cutting mechanics calculation method of drill bit tooth; Step S3: calculating a vertical penetration force of the target drill bit tooth according to a vertical penetration mechanics calculation method of drill bit tooth; Step S4: calculating a resultant force experienced by the target drill bit tooth according to a resultant force calculation method of drill bit tooth. The invention provides a calculation method for accurately obtaining drill bit tooth mechanics under different working conditions.

Claims

1. A mechanics calculation method of drill bit tooth considering rock dynamic strength and mixed crushing mode, comprising steps of: Step S1: selecting a target drill bit tooth and a target rock, and determining a type of the target drill bit tooth, a geometry of the target drill bit tooth, a rock type and rock parameters of the target rock; Step S2: using a processor for calculating a horizontal cutting force of the target drill bit tooth according to a horizontal cutting mechanics calculation method of drill bit tooth; Step S3: using the processor for calculating a vertical penetration force of the target drill bit tooth according to a vertical penetration mechanics calculation method of drill bit tooth; Step S4: using the processor for calculating a resultant force experienced by the target drill bit tooth according to a resultant force calculation method of drill bit tooth; wherein in the Step S2, the horizontal cutting mechanics calculation method of drill bit tooth is determined according to the following formula: $F_{c} = F \times D \times \frac{A}{A \times E + C} + B$ wherein: $A = \cos (γ + ω) \times [H + I + 1 - K];$ $B = \frac{2 σ_{s d} w d \sin ω \cos ϕ \cos (β + γ)}{1 - \sin (ϕ + γ + β)};$ $C = \sin ω \frac{\cos (γ + ω) + G}{M};$ $D = \frac{\sin (\frac{π}{2} - γ)}{\sin (\frac{π}{2} - γ - ω)};$ $E = \frac{\sin ω}{\cos (γ + ω)};$ $F = σ_{u c d} wd;$ $G = \sqrt{\cos^{2} (γ + ω) + 4 N \sin^{2} (\frac{π}{4} - \frac{γ + ω}{2}) + 4 \sin^{4} (\frac{π}{4} + \frac{γ + ω}{2})};$ $H = - \frac{\cos (γ + ω)}{4 \sin^{2} (\frac{π}{4} - \frac{γ + ω}{2}) + 4 N};$ $I = \frac{\sqrt{N + 1}}{2 \sin (\frac{π}{4} - \frac{γ + ω}{2})};$ $J = \frac{1}{2} \cot (\frac{π}{4} - \frac{γ + ω}{2});$ $K = \frac{G}{L};$ $L = 4 \sin^{2} (\frac{π}{4} - \frac{γ + ω}{2}) + 4 N;$ $M = 2 \sin^{2} (\frac{π}{4} + \frac{γ + ω}{2}) + 2 N;$ $N = \frac{σ_{t d}}{σ_{u c d}};$ wherein F.sub.c is the horizontal cutting force of the target drill bit tooth with a unit of N; σ.sub.ucd is the dynamic rock uniaxial compressive strength with a unit of MPa; σ.sub.td is the dynamic rock tensile strength with a unit of MPa; σ.sub.sd is the dynamic rock shear strength with a unit of MPa; γ is the caster angle of the target drill bit tooth with a unit of rad; ω is the scrap forming-compaction transition angle with a unit of rad; β is the average friction angle between contact surfaces of the target drill bit tooth and the target rock with a unit of rad; φ is the rock internal friction angle, and w is the target drill bit tooth penetration equivalent width with a unit of mm; d is the cutting depth with a unit of mm; and wherein in the Step S3, the vertical penetration mechanics calculation method of drill bit tooth is determined according to the following formula:
F.sub.t=tan(γ+β)F.sub.c wherein F.sub.t is the vertical penetration force of the target drill bit tooth with a unit of N; γ is the caster angle of the target drill bit tooth with a unit of rad; β is the average friction angle between contact surfaces of the target drill bit tooth and the target rock with a unit of rad; F.sub.c is the horizontal cutting force of the target drill bit tooth with a unit of N.

2. The mechanics calculation method of drill bit tooth considering rock dynamic strength and mixed crushing mode according to claim 1, wherein in the Step S1, the type of the target drill bit tooth comprises a cylindrical drill bit tooth and a wedge drill bit tooth; the geometry of the target drill bit tooth comprises a diameter of the cylindrical drill bit tooth, a height of the cylindrical drill bit tooth, a height of the wedge drill bit tooth, and an angle of the wedge drill bit tooth; the rock parameters comprise a static rock uniaxial compressive strength, a static rock tensile strength, a static rock shear strength, a rock internal friction angle, a dynamic rock uniaxial compressive strength, a dynamic rock tensile strength, and a dynamic rock shear strength.

3. The mechanics calculation method of drill bit tooth considering rock dynamic strength and mixed crushing mode according to claim 1, wherein in the Step S4, the resultant force calculation method of drill bit tooth is determined according to the following formula: $F_{c t} = \sqrt{{(F \times D \times \frac{A}{A \times E + C} + B)}^{2} + {(\tan (γ + β) F_{c})}^{2}}$ wherein: $A = \cos (γ + ω) \times [H + I + 1 - K];$ $B = \frac{2 σ_{s d} w d \sin ω \cos ϕ \cos (β + γ)}{1 - \sin (ϕ + γ + β)};$ $C = \sin ω \frac{\cos (γ + ω) + G}{M};$ $D = \frac{\sin (\frac{π}{2} - γ)}{\sin (\frac{π}{2} - γ - ω)};$ $E = \frac{\sin ω}{\cos (γ + ω)};$ $F = σ_{u c d} wd;$ $G = \sqrt{\cos^{2} (γ + ω) + 4 N \sin^{2} (\frac{π}{4} - \frac{γ + ω}{2}) + 4 \sin^{4} (\frac{π}{4} + \frac{γ + ω}{2})};$ $H = - \frac{\cos (γ + ω)}{4 \sin^{2} (\frac{π}{4} - \frac{γ + ω}{2}) + 4 N};$ $I = \frac{\sqrt{N + 1}}{2 \sin (\frac{π}{4} - \frac{γ + ω}{2})};$ $J = \frac{1}{2} \cot (\frac{π}{4} - \frac{γ + ω}{2});$ $K = \frac{G}{L};$ $L = 4 \sin^{2} (\frac{π}{4} - \frac{γ + ω}{2}) + 4 N;$ $M = 2 \sin^{2} (\frac{π}{4} + \frac{γ + ω}{2}) + 2 N;$ $N = \frac{σ_{t d}}{σ_{u c d}};$ wherein F.sub.c is the horizontal cutting force of the target drill bit tooth with a unit of N; σ.sub.ucd is the dynamic rock uniaxial compressive strength with a unit of MPa; σ.sub.td is the dynamic rock tensile strength with a unit of MPa; σ.sub.sd is the dynamic rock shear strength with a unit of MPa; γ is the caster angle of the target drill bit tooth with a unit of rad; ω is the scrap forming-compaction transition angle with a unit of rad; β is the average friction angle between contact surfaces of the target drill bit tooth and the target rock with a unit of rad; φ is the rock internal friction angle, and w is the target drill bit tooth penetration equivalent width with a unit of mm; d is the cutting depth with a unit of mm; F.sub.ct is the resultant force of the target drill bit tooth with a unit of N.

4. The mechanics calculation method of drill bit tooth considering rock dynamic strength and mixed crushing mode according to claim 2, wherein the static rock uniaxial compressive strength, the static rock tensile strength, the static rock shear strength and the rock internal friction angle of the rock parameters are measured by field logging data or laboratory rock mechanics experiments; the dynamic rock uniaxial compressive strength, the dynamic rock tensile strength and the dynamic rock shear strength of the rock parameters are obtained according to steps of: Step S11: using a SHPB for measuring the dynamic rock uniaxial compressive strength by SHPB rock mechanics experiments, and using the processor for establishing a relationship among the dynamic rock uniaxial compressive strength, the static rock uniaxial compressive strength and a dynamic loading strain rate of the load, which is expressed as follows: $\frac{σ_{u c d}}{σ_{u c}} = {\begin{matrix} a_{1} {\dot{ε}}^{1 / (1 + n_{c})} (\dot{ε} < {\dot{ε}}^{*}) \\ a_{2} {\dot{ε}}^{1 / n} (\dot{ε} \geq {\dot{ε}}^{*}) \end{matrix}$ Step S12: using the SHPB for measuring the dynamic rock tensile strength by the SHPB rock mechanics experiments, the dynamic rock tensile strength being the radial fracturing indirect tensile strength, and using the processor for establishing a relationship among the dynamic rock tensile strength, the static rock tensile strength and the dynamic loading strain rate of the load, which is expressed as follows: $\frac{σ_{td}}{σ_{t}} = {\begin{matrix} b_{1} {\dot{ε}}^{1 / (1 + n_{c})} (\dot{ε} < {\dot{ε}}^{*}) \\ b_{2} {\dot{ε}}^{1 / n} (\dot{ε} \geq {\dot{ε}}^{*}) \end{matrix}$ Step S13: using the SHPB for measuring the dynamic rock shear strength by the SHPB rock mechanics experiments, and using the processor for establishing a relationship among the dynamic rock shear strength, the static rock shear strength and the dynamic loading strain rate of the load, which is expressed as follows: $\frac{σ_{s d}}{σ_{s}} = {\begin{matrix} c_{1} {\dot{ε}}^{1 / (1 + n_{c})} (\dot{ε} < {\dot{ε}}^{*}) \\ c_{2} {\dot{ε}}^{1 / n} (\dot{ε} \geq {\dot{ε}}^{*}) \end{matrix}$ wherein a.sub.1, a.sub.2, b.sub.1, b.sub.2, c.sub.1, c.sub.2, n, n.sub.c are the fit coefficients, dimensionless; a.sub.uc is the static rock uniaxial compressive strength with a unit of MPa; σ.sub.t is the static rock tensile strength with a unit of MPa; σ.sub.s is the static rock shear strength with a unit of MPa; σ.sub.ucd is the dynamic rock uniaxial compressive strength with a unit of MPa; σ.sub.td is the dynamic rock tensile strength with a unit of MPa; σ.sub.sd is the dynamic rock shear strength with a unit of MPa; {dot over (ε)} is the dynamic loading strain rate of the load with a unit of s.sup.−1, and {dot over (ε)}* is the dynamic loading critical strain rate of the load with a unit of s.sup.−1; a calculation method of the dynamic loading strain rate of the load {dot over (ε)} in the process of crushing rocks with the target drill bit tooth is expressed as follows: $\dot{ε} = \frac{1.4 v_{c} \sin γ}{d \sin (γ + ω)}$ wherein {dot over (ε)} is the dynamic loading strain rate of the load with a unit of s.sup.−1; v.sub.c is the cutting tooth speed with a unit of mm/s; d is the cutting depth with a unit of mm; γ is the caster angle of the target drill bit tooth with a unit of rad; ω is the scrap forming-compaction transition angle with a unit of rad.

5. The mechanics calculation method of drill bit tooth considering rock dynamic strength and mixed crushing mode according to claim 1, wherein a relationship between the average friction angle between the contact surfaces of the target drill bit tooth and the target rock and the caster angle of the target drill bit tooth is specifically expressed as follows:
β=e.sub.1γ+e.sub.2 wherein e.sub.1 and e.sub.2 are the coefficients of the fitting formula, dimensionless; p is the average friction angle between the contact surfaces of the target drill bit tooth and the target rock with a unit of rad; γ is the caster angle of the target drill bit tooth with a unit of rad.

6. The mechanics calculation method of drill bit tooth considering rock dynamic strength and mixed crushing mode according to claim 5, wherein the relationship between the average friction angle between the contact surfaces of the target drill bit tooth and the target rock and the caster angle of the target drill bit tooth is determined by steps of: Step S31: using the SHPB for conducting n groups of rock-crushing experiments of the target drill bit tooth with different caster angles to obtain the horizontal cutting force and the vertical penetration force of the target drill bit tooth during the experiment, and using the processor for obtaining the average friction angle between the contact surfaces of the target drill bit tooth and the target rock according to the following formula: $β = \arctan (\frac{F_{t}}{F_{c}}) - γ$ wherein β is the average friction angle between the contact surfaces of the target drill bit tooth and the target rock with a unit of rad; γ is the caster angle of the target drill bit tooth with a unit of rad; F.sub.t is the vertical penetration force of the target drill bit tooth with a unit of N; F.sub.c is the horizontal cutting force of the target drill bit tooth with a unit of N; Step S32: using the processor for determining the relationship between the average friction angle between the contact surfaces of the target drill bit tooth and the target rock and the caster angle according to the fitting method.

7. The mechanics calculation method of drill bit tooth considering rock dynamic strength and mixed crushing mode according to claim 1, wherein a relationship between the scrap forming-compaction transition angle and the cutting depth is determined by n groups of rock-crushing experiments of the target drill bit tooth with different penetration depths and a regression method, which is expressed as follows:
ω=k.sub.1d.sup.n+k.sub.2d+k.sub.3 wherein k.sub.1, k.sub.2, k.sub.3 are the coefficients of the fitting formula, dimensionless; ω is the scrap forming-compaction transition angle with a unit of rad; d is the cutting depth with a unit of mm, and n is the number of groups of rock-crush experiments of the target drill bit tooth with penetration depths.

8. The mechanics calculation method of drill bit tooth considering rock dynamic strength and mixed crushing mode according to claim 1, wherein a calculation method of the target drill bit tooth penetration equivalent width is as follows: $w = \frac{R^{2}}{d} \arccos (\frac{R - d}{R}) - \frac{R - d}{d} \sqrt{R^{2} - (R^{2} - d^{2})}$ wherein R is the diameter of the cylindrical drill bit tooth with a unit of mm; w is the target drill bit tooth penetration equivalent width with a unit of mm; d is the cutting depth with a unit of mm.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0039] Upon reading the following detailed description of preferred embodiments, various advantages and benefits will be apparent to those of ordinary skill in the art. The drawings are for the purpose of explaining preferred embodiments only, and do not constitute improper limitations on the present invention. The same components are also denoted by the same reference numerals throughout the drawings. In the drawings:

[0040] FIG. 1 is a flow chart of a mechanics calculation method of drill bit tooth considering rock dynamic strength and mixed crushing mode according to Embodiment 1 of the invention;

[0041] FIG. 2 is a schematic diagram of a relationship between a horizontal cutting force and a vertical penetration force according to Embodiment 1 of the invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0042] The invention will be further described below in conjunction with the accompanying drawings, and the protection scope of the invention is not limited to the following.

Embodiment 1

[0043] 1. A mechanics calculation method of drill bit tooth considering rock dynamic strength and mixed crushing mode.

[0044] As shown in FIGS. 1 and 2, a mechanics calculation method of drill bit tooth considering rock dynamic strength and mixed crushing mode includes the following steps:

[0045] Step S1: a target drill bit tooth and a target rock are selected, and a type of the target drill bit tooth, a geometry of the target drill bit tooth, a rock type and rock parameters of the target rock are determined;

[0046] Step S2: a horizontal cutting force of the target drill bit tooth is calculated according to a horizontal cutting mechanics calculation method of drill bit tooth;

[0047] Step S3: a vertical penetration force of the target drill bit tooth is calculated according to a vertical penetration mechanics calculation method of drill bit tooth;

[0048] Step S4: a resultant force experienced by the target drill bit tooth is calculated according to a resultant force calculation method of drill bit tooth.

[0049] In the Step S1, the type of the target drill bit tooth includes a cylindrical drill bit tooth and a wedge drill bit tooth; the geometry of the target drill bit tooth comprises a diameter of the cylindrical drill bit tooth, a height of the cylindrical drill bit tooth, a height of the wedge drill bit tooth, and an angle of the wedge drill bit tooth; the rock parameters comprise a static rock uniaxial compressive strength, a static rock tensile strength, a static rock shear strength, a rock internal friction angle, a dynamic rock uniaxial compressive strength, a dynamic rock tensile strength, and a dynamic rock shear strength.

[0050] In the Step S2, the horizontal cutting mechanics calculation method of drill bit tooth is determined according to the following formula:

[00011] $F_{c} = F ⨯ D ⨯ \frac{A}{A ⨯ E + C} + B$

[0051] wherein:

[00012] $A = \cos (γ + ω) ⨯ [H + I + J - K];$ $B = \frac{2 σ_{s d} wd \sin ω \cos φcos (β + γ)}{1 - \sin (φ + γ + β)};$ $C = \sin ω \frac{\cos (γ + ω) + G}{M};$ $D = \frac{\sin (\frac{π}{2} - γ)}{\sin (\frac{π}{2} - γ - ω)};$ $E = \frac{\sin ω}{\cos (γ + ω)};$ $F = σ_{u c d} wd;$ $G = \sqrt{\cos^{2} (γ + ω) + 4 N \sin^{2} (\frac{π}{4} - \frac{γ + ω}{2}) + 4 \sin^{4} (\frac{π}{4} + \frac{γ + ω}{2})};$ $H = - \frac{\cos (γ + ω)}{4 \sin^{2} (\frac{π}{4} - \frac{γ + ω}{2}) + 4 N};$ $I = \frac{\sqrt{N + 1}}{2 \sin (\frac{π}{4} - \frac{γ + ω}{2})};$ $J = \frac{1}{2} \cot (\frac{π}{4} - \frac{γ + ω}{2});$ $K = \frac{G}{L};$ $L = 4 \sin^{2} (\frac{π}{4} - \frac{γ + ω}{2}) + 4 N;$ $M = 2 \sin^{2} (\frac{π}{4} + \frac{γ + ω}{2}) + 2 N;$ $N = \frac{σ_{t d}}{σ_{u c d}};$

[0052] wherein F.sub.c is the horizontal cutting force of the target drill bit tooth with a unit of N; σ.sub.ucd is the dynamic rock uniaxial compressive strength with a unit of MPa; σ.sub.td is the dynamic rock tensile strength with a unit of MPa; σ.sub.sd is the dynamic rock shear strength with a unit of MPa; γ is the caster angle of the target drill bit tooth with a unit of rad; ω is the scrap forming-compaction transition angle with a unit of rad; β is the average friction angle between contact surfaces of the target drill bit tooth and the target rock with a unit of rad; φ is the rock internal friction angle, and w is the target drill bit tooth penetration equivalent width with a unit of mm; d is the cutting depth with a unit of mm.

[0053] In the Step S3, the vertical penetration mechanics calculation method of drill bit tooth is determined according to the following formula:

F.sub.t=tan(γ+β)F.sub.c

[0054] wherein F.sub.t is the vertical penetration force of the target drill bit tooth with a unit of N; γ is the caster angle of the target drill bit tooth with a unit of rad; β is the average friction angle between contact surfaces of the target drill bit tooth and the target rock with a unit of rad; F.sub.c is the horizontal cutting force of the target drill bit tooth with a unit of N.

[0055] Furthermore, in the Step S4, the resultant force calculation method of drill bit tooth is determined according to the following formula:

[00013] $F_{c t} = \sqrt{{(F ⨯ D ⨯ \frac{A}{A ⨯ E + C} + B)}^{2} + {(\tan (γ + β) F_{c})}^{2}}$

[0056] wherein:

[00014] $A = \cos (γ + ω) ⨯ [H + I + J - K];$ $B = \frac{2 σ_{s d} wd \sin ω \cos φcos (β + γ)}{1 - \sin (φ + γ + β)};$ $C = \sin ω \frac{\cos (γ + ω) + G}{M};$ $D = \frac{\sin (\frac{π}{2} - γ)}{\sin (\frac{π}{2} - γ - ω)};$ $E = \frac{\sin ω}{\cos (γ + ω)};$ $F = σ_{u c d} wd;$ $G = \sqrt{\cos^{2} (γ + ω) + 4 N \sin^{2} (\frac{π}{4} - \frac{γ + ω}{2}) + 4 \sin^{4} (\frac{π}{4} + \frac{γ + ω}{2})};$ $H = - \frac{\cos (γ + ω)}{4 \sin^{2} (\frac{π}{4} - \frac{γ + ω}{2}) + 4 N};$ $I = \frac{\sqrt{N + 1}}{2 \sin (\frac{π}{4} - \frac{γ + ω}{2})};$ $J = \frac{1}{2} \cot (\frac{π}{4} - \frac{γ + ω}{2});$ $K = \frac{G}{L};$ $L = 4 \sin^{2} (\frac{π}{4} - \frac{γ + ω}{2}) + 4 N;$ $M = 2 \sin^{2} (\frac{π}{4} + \frac{γ + ω}{2}) + 2 N;$ $N = \frac{σ_{t d}}{σ_{u c d}};$

[0057] wherein F.sub.c is the horizontal cutting force of the target drill bit tooth with a unit of N; σ.sub.ucd is the dynamic rock uniaxial compressive strength with a unit of MPa; σ.sub.td is the dynamic rock tensile strength with a unit of MPa; σ.sub.sd is the dynamic rock shear strength with a unit of MPa; γ is the caster angle of the target drill bit tooth with a unit of rad; ω is the scrap forming-compaction transition angle with a unit of rad; β is the average friction angle between contact surfaces of the target drill bit tooth and the target rock with a unit of rad; φ is the rock internal friction angle, and w is the target drill bit tooth penetration equivalent width with a unit of mm; d is the cutting depth with a unit of mm; F.sub.ct is the resultant force of the target drill bit tooth with a unit of N.

[0058] The static rock uniaxial compressive strength, the static rock tensile strength, the static rock shear strength and the rock internal friction angle of the rock parameters are measured by field logging data or laboratory rock mechanics experiments; the dynamic rock uniaxial compressive strength, the dynamic rock tensile strength and the dynamic rock shear strength of the rock parameters are obtained according to steps of:

[0059] Step S11: the dynamic rock uniaxial compressive strength is measured by SHPB rock mechanics experiments, and a relationship is established among the dynamic rock uniaxial compressive strength, the static rock uniaxial compressive strength and a dynamic loading strain rate of the load, which is expressed as follows:

[00015] $\frac{σ_{u c d}}{σ_{u c}} = {\begin{matrix} a_{1} {\dot{ε}}^{1 / (1 + n_{c})} (\dot{ε} < {\dot{ε}}^{*}) \\ a_{2} {\dot{ε}}^{1 / n} (\dot{ε} \geq {\dot{ε}}^{*}) \end{matrix}$

[0060] Step S12: the dynamic rock tensile strength is measured by SHPB rock mechanics experiments, the dynamic rock tensile strength being the radial fracturing indirect tensile strength, and a relationship is established among the dynamic rock tensile strength, the static rock tensile strength and the dynamic loading strain rate of the load, which is expressed as follows:

[00016] $\frac{σ_{td}}{σ_{t}} = {\begin{matrix} b_{1} {\dot{ε}}^{1 / (1 + n_{c})} (\dot{ε} < {\dot{ε}}^{*}) \\ b_{2} {\dot{ε}}^{1 / n} (\dot{ε} \geq {\dot{ε}}^{*}) \end{matrix}$

[0061] Step S13: the dynamic rock shear strength is measured by SHPB rock mechanics experiments, and s relationship is established among the dynamic rock shear strength, the static rock shear strength and the dynamic loading strain rate of the load, which is expressed as follows:

[00017] $\frac{σ_{s d}}{σ_{s}} = {\begin{matrix} c_{1} {\dot{ε}}^{1 / (1 + n_{c})} (\dot{ε} < {\dot{ε}}^{*}) \\ c_{2} {\dot{ε}}^{1 / n} (\dot{ε} \geq {\dot{ε}}^{*}) \end{matrix}$

wherein a.sub.1, a.sub.2, b.sub.1, b.sub.2, c.sub.1, c.sub.2, n, n.sub.c are the fit coefficients, dimensionless; σ.sub.uc is the static rock uniaxial compressive strength with a unit of MPa; σ.sub.t is the static rock tensile strength with a unit of MPa; σ.sub.s is the static rock shear strength with a unit of MPa; σ.sub.ucd is the dynamic rock uniaxial compressive strength with a unit of MPa; σ.sub.td is the dynamic rock tensile strength with a unit of MPa; σ.sub.sd is the dynamic rock shear strength with a unit of MPa; {dot over (ε)} is the dynamic loading strain rate of the load with a unit of s.sup.−1, and {dot over (ε)}* is the dynamic loading critical strain rate of the load with a unit of s.sup.−1.

[0062] A calculation method of the dynamic loading strain rate of the load {dot over (ε)} in the process of crushing rocks with the target drill bit tooth is expressed as follows:

[00018] $\dot{ε} = \frac{1.4 v_{c} \sin γ}{d \sin (γ + ω)}$

[0063] wherein {dot over (ε)} is the dynamic loading strain rate of the load with a unit of s−1; v.sub.c is the cutting tooth speed with a unit of mm/s; d is the cutting depth with a unit of mm; γ is the caster angle of the target drill bit tooth with a unit of rad; ω is the scrap forming-compaction transition angle with a unit of rad.

[0064] A relationship between the average friction angle between the contact surfaces of the target drill bit tooth and the target rock and the caster angle of the target drill bit tooth is specifically expressed as follows:

β=e.sub.1γ+e.sub.2

[0065] wherein e.sub.1 and e.sub.2 are the coefficients of the fitting formula above, dimensionless; β is the average friction angle between the contact surfaces of the target drill bit tooth and the target rock with a unit of rad; γ is the caster angle of the target drill bit tooth with a unit of rad.

[0066] The relationship between the average friction angle between the contact surfaces of the target drill bit tooth and the target rock and the caster angle of the target drill bit tooth may be determined by steps of:

[0067] Step S31: n groups of rock-crushing experiments of the target drill bit tooth with different caster angles are conducted to obtain the horizontal cutting force and vertical penetration force of the target drill bit tooth during the experiment, and the average friction angle between the contact surfaces of the target drill bit tooth and the target rock is obtained according to the following formula:

[00019] $β = \arctan (\frac{F_{t}}{F_{c}}) - γ$

[0068] wherein β is the average friction angle between the contact surfaces of the target drill bit tooth and the target rock with a unit of rad; γ is the caster angle of the target drill bit tooth with a unit of rad; F.sub.t is the vertical penetration force of the target drill bit tooth with a unit of N; F.sub.c is the horizontal cutting force of the target drill bit tooth with a unit of N;

[0069] Step S32: the relationship between the average friction angle between the contact surfaces of the target drill bit tooth and the target rock and the caster angle is determined according to the fitting method.

[0070] A relationship between the scrap forming-compaction transition angle and the cutting depth is determined by n groups of rock-crushing experiments of the target drill bit tooth with different penetration depths and a regression method, which is expressed as follows:

ω=k.sub.1d.sup.n+k.sub.2d+k.sub.3

[0071] wherein k.sub.1, k.sub.2, k.sub.3 are the coefficients of the fitting formula above, dimensionless; ω is the scrap forming-compaction transition angle with a unit of rad; d is the cutting depth with a unit of mm, and n is the number of groups of rock-crush experiments of the target drill bit tooth with penetration depths.

[0072] A calculation method of the target drill bit tooth penetration equivalent width is as follows:

[00020] $w = \frac{R^{2}}{d} \arccos (\frac{R - d}{R}) - \frac{R - d}{d} \sqrt{R^{2} - (R^{2} - d^{2})}$

[0073] wherein R is the diameter of the cylindrical drill bit tooth with a unit of mm; w is the target drill bit tooth penetration equivalent width with a unit of mm; d is the cutting depth with a unit of mm.

[0074] The invention discloses a mechanics calculation method of drill bit tooth considering rock dynamic strength and mixed crushing mode. The calculation method includes: (1) a target drill bit tooth and a target rock are selected, and a type of the target drill bit tooth, a geometry of the target drill bit tooth, a rock type and rock parameters of the target rock are determined; (2) a horizontal cutting force of the target drill bit tooth is calculated according to a horizontal cutting mechanics calculation method of drill bit tooth; (3) a vertical penetration force of the target drill bit tooth is calculated according to a vertical penetration mechanics calculation method of drill bit tooth; (4) a resultant force experienced by the target drill bit tooth is calculated according to a resultant force calculation method of drill bit tooth. The invention discloses a mechanics calculation process of drill bit tooth considering the rock dynamic strength and the mixed crushing mode, which provides a calculation method that may accurately and quickly obtain the mechanics of drill bit tooth under different working conditions.

[0075] The invention establishes a mechanical calculation method of drill bit tooth considering the rock dynamic strength and the mixed crushing mode. The invention fully considers the real mechanical state in the process of crushing rocks with the target drill bit tooth, as well as the rock dynamic strength, the mixed crushing mode, the target drill bit tooth speed, the target drill bit tooth shape and the rock strain rate, while overcoming the drawbacks that the existing analytical calculation methods of drill bit tooth force consider a single rock failure mode and only consider the static or quasi-static rock strength. The invention provides important guidance and support for drill bit design and development, drilling engineering parameter optimization, drill tool optimization or selection, penetration speed increasing, cost reduction and efficiency improvement. The invention has broad application prospects.

[0076] So far, those skilled in the art realize that although embodiments of the invention have been shown and described in detail herein, numerous other variations or modifications consistent with the principles of the invention may be directly determined or derived from the disclosure without departing from the spirit and scope of the invention. Accordingly, the scope of the invention should be understood and deemed to cover all such other variations or modifications.

MECHANICS CALCULATION METHOD OF DRILL BIT TOOTH CONSIDERING ROCK DYNAMIC STRENGTH AND MIXED CRUSHING MODE

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E21B10/43

FIXED CONSTRUCTIONS

Classification Explorer

E21B12/02

FIXED CONSTRUCTIONS

Abstract

Claims

Description