Pipe connection compensation device by magnetic fluid sealing

Abstract

A pipe connection compensation device by magnetic fluid sealing comprising a compensation pipe, sealed end cap, coil, annular permanent magnet and tightening rod is provided, designed and configured in a novel manner to ensure the pipe connection compensation device by magnetic fluid sealing achieves a better sealing effect.

Claims

1. A pipe connection compensation device by magnetic fluid sealing comprises a first flange pipe and a second flange pipe, the second flange pipe comprises the second flange plate and the second joint pipe, the second flange plate is concentrically welded and fixed to the second joint pipe; the first flange pipe comprises a first flange plate, a first joint pipe and a flange ring, the first flange plate and the flange ring are welded and fixed via the first joint pipe; wherein the pipe connection compensation device by magnetic fluid sealing further comprises a connection compensation device, the connection compensation device comprises a compensation pipe, a sealed end cap, a coil, an annular permanent magnet and a tightening rod; one end of the compensation pipe is connected to the flange ring, the other end of the compensation pipe is connected to the sealed end cap, and the second joint pipe penetrates into the sealed end cap; the sealed end cap fits with the second joint pipe in clearance fit; an inner wall of the sealed end cap is provided with a first annular liquid storage groove and a second annular liquid storage groove, the outer wall of the sealed end cap is provided with the a first annular groove and a second annular groove, which are axially arranged; the coil is wound around the first annular groove, and the annular permanent magnet is installed in the second annular groove; the radial gap between the sealed end cap and the second joint pipe, the first annular liquid storage groove, the second annular liquid storage groove, and a radial gap between the compensation pipe and the sealed end cap form a gap chamber, which is filled with the magnetic fluid; the first flange pipe and the second flange pipe are connected via the tightening rod; one end of the tightening rod fixes the first flange tube through fastening nuts, and the other end of the tightening rod is provided with the limiting nuts for limiting the axial limit position of the second flange pipe.

2. The pipe connection compensation device by magnetic fluid sealing according to claim 1, wherein, one end face of the second annular groove is on the same normal plane as one end face of the first annular liquid storage groove.

3. The pipe connection compensation device by magnetic fluid sealing according to claim 1, wherein, the first annular groove is located between the first annular liquid storage groove and the second annular liquid storage groove.

4. The pipe connection compensation device by magnetic fluid sealing according to claim 1, wherein, the sealed end cap is provided with a filling hole and the filling hole is in communication with the gap chamber.

5. The pipe connection compensation device by magnetic fluid sealing according to claim 1, wherein, the outer ring of the second joint pipe inserted into the sealed end cap is provided with a liquid storage groove.

6. The pipe connection compensation device by magnetic fluid sealing according to claim 1, wherein, the nominal diameter of the second joint pipe and the first joint pipe are both d.sub.0; the wall thickness of the second joint pipe is δ.sub.1, the wall thickness of the first joint pipe is δ.sub.2, wherein, the determining equation of the wall thickness δ.sub.1 of the second joint pipe is: ${\delta }_1=\frac{P_0{D}_0}{{2\left[\delta \right]}^t{E}_j},$ when δ.sub.1≤4 mm, δ.sub.1=4 mm Where, d.sub.0—Nominal diameter of the second joint pipe, mm; P.sub.0—Design pressure of fluid in the pipeline, Mpa; D.sub.0—The outer diameter of the second joint pipe, D.sub.0=d.sub.0+2δ.sub.1, mm; [δ].sup.t—Material allowable stress of the second joint pipe, Mpa; E.sub.j—Welded joint coefficient of the second joint pipe; the wall thickness δ.sub.2 of the first joint pipe is not less than the wall thickness δ.sub.1 of the second joint pipe.

7. The pipe connection compensation device by magnetic fluid sealing according to claim 1, wherein, the number of turns N and the current I of the coil should satisfy the following equation: $\mathrm{IN}\ge \frac{P_0{L}_{41}\left[{\left(d_0+2{\delta }_1+2\mathrm{.Math.}\right)}^2-{\left(d_0+2{\delta }_1\right)}^2\right]}{10^6\zeta {\mathrm{Bd}}_{41}}$ Where, P.sub.0—Design pressure of fluid in the pipeline, Mpa; ζ—Safety factor, 0.8˜0.9; B—Magnetic field strength in the coil generated by the magnetic fluid, A/s; I—Current in the coil, A; N—Number of turns of the coil; L.sub.41—Width of the coil, L.sub.41=9δ.sub.1, mm; d.sub.41—Inner diameter of the sealed end cap, d.sub.41=2δ.sub.1+d.sub.0+2ε, mm; ε—Radial clearance between the second joint pipe and the sealed end cap, ε=0.02 d.sub.0, mm.

8. The pipe connection compensation device by magnetic fluid sealing according to claim 1, wherein, the cross-sectional width H of the annular permanent magnet should satisfy the following equation:
ρ.sub.1L.sub.410HK.sub.4C.sub.4>4ρ.sub.2L.sub.411L.sub.48 Where, ρ.sub.1—Density of the annular permanent magnet, kg/m.sup.3; K.sub.4—Safety factor of the annular permanent magnet, 0.6˜0.8; H—Cross-sectional width of the annular permanent magnet, mm; L.sub.410—Cross-sectional length of the annular permanent magnet, L.sub.410=δ.sub.1, mm; L.sub.411—Cross-sectional width of the annular liquid storage groove, L.sub.411=δ.sub.1, mm; L.sub.48—Length of the annular permanent magnet, L.sub.48=1.2δ.sub.1, mm; ρ.sub.2—Density of the magnetic fluid, kg/m.sup.3; C.sub.4—Residual magnetic coefficient of the annular permanent magnet.

Description

DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is the structural view of the pipe connection compensation device by magnetic fluid sealing according to the present invention.

(2) FIG. 2 is a profile drawing of the sealed end cap according to the present invention.

(3) FIG. 3 is a partial enlarged view of the sealed end cap of FIG. 2;

(4) In the drawings: 1—the first flange plate; 2—the second flange plate; 3—the first joint pipe; 4—the second joint pipe; 5—the sealed end cap; 6—the coil; 7—the annular permanent magnet; 8—the first nut; 9—the second nut; 10—the tightening rod; 11—the first sealing gasket; 12—the second sealing gasket; 13—the flange ring; 14—the compensation pipe; 15—the first limit nut; 16—the second limit nut; a—filling hole; b—the first annular liquid storage groove; c—the second annular liquid storage groove; d—the magnetic fluid; g—the first annular groove; h—the second annular groove.

EMBODIMENTS

(5) Hereunder the invention will be further detailed in combination with the following drawings and specific embodiments, but the protection scope of the present invention is not limited thereto.

(6) As shown in FIG. 1 and FIG. 2, the pipe connection compensation device by magnetic fluid sealing comprises a first flange pipe and a second flange pipe and a connection compensation device, the second flange pipe comprises a second flange plate 2 and a second joint pipe 4, the second flange plate 2 is concentrically welded and fixed to the second joint pipe 4; the first flange pipe comprises a first flange plate 1, a first joint pipe 3 and the flange ring 13, the first flange plate 1 and the flange ring 13 are welded and fixed via the first joint pipe 3.

(7) The connection compensation device comprises the compensation pipe 14, the sealed end cap 5, the coil 6, the annular permanent magnet 7 and the tightening rod 10; one end of the compensation pipe 14 is connected to the flange ring 13, the other end of the compensation pipe 14 is connected to the sealed end cap 5, and the second joint pipe 4 penetrates into the sealed end cap 5; the sealed end cap 5 fit the second joint pipe 4 in clearance; an inner wall of the sealed end cap 5 is provided with a first annular liquid storage groove b and a second annular liquid storage groove c, the outer wall of the sealed end cap 5 is provided with a first annular groove g and a second annular groove h, which are axially arranged; the coil 6 is wound around the first annular groove g, and the annular permanent magnet 7 is installed in the second annular groove h; the radial gap between the sealed end cap 5 and the second joint pipe 4, the first annular liquid storage groove b, the second annular liquid storage groove c, and the radial gap between the compensation pipe 14 and the sealed end cap 5 form a gap chamber, which is filled with the magnetic fluid d; the first flange pipe and the second flange pipe are connected via the tightening rod 10; one end of the tightening rod 10 is locked and fixed to the first flange plate 1 by the first nut 8 and the second nut 9, the other end of the tightening rod 10 is provided with the first limit nut 15 and the second limit nut 16; the second flange plate 2 is limited between the first limit nut 15 and the second limit nut 16 for limiting the position of the axial movement of the second flange pipe. It can be seen from FIG. 1 that the maximum movement position of the second flange plate 2 is at the first limit nut 15, and the minimum movement position of the second flange plate 2 is at the second limit nut 16. It can be seen from figure that the movement distance of the second flange plate 2 is u.

(8) One end face of the second annular groove h is on the same normal plane as one end face of the first annular liquid storage groove b; the first annular groove g is located between the first annular liquid storage groove b and the second annular liquid storage groove c; the sealed end cap 5 is provided with a filling hole a, and the filling hole a is in communication with the gap chamber, the magnetic fluid d can be replenished into the gap chamber through the filling hole a; when the magnetic fluid d is replenished, the filing hole a is closed by the screw; due to the action of the magnetic field of the annular permanent magnet 7 on the sealed end cap 5, the magnetic fluid d is filled in the gap chamber to achieve a good sealing effect; when the pressure in the pipeline is large, the coil 6 is supplied with alternating current to enhance the magnetic field at the sealed end cap 5 to ensure that the magnetic fluid d does not overflow; and at the same time, the first limiting nut 15 and the second limiting nut 16 define the axial position of the second flange plate 2, making the present invention well perform axial compensation for the expansion and contraction of the pipeline, and axial deformation, etc.

(9) The outer ring of the second joint pipe 4 inserted into the sealed end cap 5 is provided with a liquid storage groove, and the liquid storage groove is a helical groove, which increases the liquid storage capacity and the friction force of the liquid storage medium in the flow, ensuring the sealing effect.

(10) The material for the first joint pipe 3, the second joint pipe 4, the first nut 8, the second nut 9, the tightening rod 10, the flange ring 13, the compensation pipe 14, the first limiting nut 15, the second limiting nut 16 is stainless steel or high-quality structural steel, and the sealed end cap 5 is made of magnetic conductive metal material.

(11) The nominal diameter of the second joint pipe 4 and the first joint pipe 3 are both d0; the wall thickness of the second joint pipe 4 is δ.sub.1, the wall thickness of the first joint pipe 3 is δ.sub.2, and the determining equation of the wall thickness δ.sub.1 of the second joint pipe 4 is:

(12) ${\delta }_1=\frac{P_0{D}_0}{{2\left[\delta \right]}^t{E}_j},$
when δ.sub.1≤4 mm, δ.sub.1=4 mm
Where,

(13) d.sub.0—Nominal diameter of the second joint pipe 4, mm;

(14) P.sub.0—Design pressure of fluid in the pipeline, Mpa;

(15) D.sub.0—The outer diameter of the second joint pipe 4, D.sub.0=d.sub.0+2δ.sub.1, mm;

(16) [δ].sup.t—Material allowable stress of the second joint pipe 4, Mpa;

(17) E.sub.j—Welded joint coefficient of the second joint pipe 4;

(18) The wall thickness δ.sub.2 of the first joint pipe 3 is not less than the wall thickness δ.sub.1 of the second joint pipe 4.

(19) The number of turns N and the current I of the coil 6 should satisfy the following equation:

(20) $\mathrm{IN}\ge \frac{P_0{L}_{41}\left[{\left(d_0+2{\delta }_1+2\mathrm{.Math.}\right)}^2-{\left(d_0+2{\delta }_1\right)}^2\right]}{10^6\zeta {\mathrm{Bd}}_{41}}$
Where,

(21) P.sub.0—Design pressure of fluid in the pipeline, Mpa;

(22) ζ—Safety factor, 0.8˜0.9;

(23) B—Magnetic field strength in the coil generated by the magnetic fluid d, A/s;

(24) I—Current in the coil 6, A;

(25) N—Number of turns of the coil 6;

(26) L.sub.41—Width of the coil 6, L.sub.41=9δ.sub.1, mm;

(27) d.sub.41—Inner diameter of the sealed end cap 5, d.sub.41=2δ.sub.1+d.sub.0+2ε, mm;

(28) ε—Radial clearance between the second joint pipe 4 and the sealed end cap 5, ε=0.02 d.sub.0, mm.

(29) The cross-sectional width H of the annular permanent magnet 7 should satisfy the following equation:
ρ.sub.1L.sub.410HK.sub.4C.sub.4>4ρ.sub.2L.sub.411L.sub.48

(30) Where,

(31) ρ.sub.1—Density of the annular permanent magnet 7, kg/m.sup.3;

(32) K.sub.4—Safety factor of the annular permanent magnet 7, 0.6˜0.8;

(33) H—Cross-sectional width of the annular permanent magnet 7, mm;

(34) L.sub.410—Cross-sectional length of the annular permanent magnet 7, L.sub.410=δ.sub.1, mm;

(35) L.sub.411—Cross-sectional width of the first annular liquid storage groove b, L.sub.411=δ.sub.1, mm;

(36) L.sub.48—Length of the annular permanent magnet 7, L.sub.48=1.2δ.sub.1, mm;

(37) ρ.sub.2—Density of the magnetic fluid d, kg/m.sup.3;

(38) C.sub.4—Residual magnetic coefficient of the annular permanent magnet 7.

EXAMPLE

(39) Taking a certain clean water transport pipeline as an example, the inner diameter of the pipeline is 50 mm and design inner pressure P.sub.0 is 4 MPa. The pipeline uses flange joints. The nominal diameter do of the second joint pipe (4) and the first joint pipe (3) are both 50 mm. The first joint pipe (3) and the second joint pipe (4) are made of material Q345D, and the allowable stress of the material [δ].sup.τ is 174 MPa; according to the Chinese standard “Steel Pressure Vessel” GB150-1998, the welded joint coefficient E.sub.1 of the first joint pipe (3) and the second joint pipe (4) is 0.9. The calculation function of wall thickness δ.sub.1 of the second joint pipe 4 is:

(40) ${\delta }_1=\frac{P_0{D}_0}{{2\left[\delta \right]}^t{E}_j}$
Where,

(41) d.sub.0—Nominal diameter of the second joint pipe 4, mm;

(42) P.sub.0—Design pressure of fluid in the pipeline, Mpa;

(43) D.sub.0—The outer diameter of the second joint pipe 4, D.sub.0=d.sub.0+2δ.sub.1, mm;

(44) [δ].sup.t—Material allowable stress of the second joint pipe 4, Mpa;

(45) E.sub.j—Welded joint coefficient of the second joint pipe 4;

(46) The wall thickness δ.sub.1 of the second joint pipe 4 calculated by the above formula is 0.65 mm, since δ.sub.1≤4 mm, δ.sub.1=4 mm. δ.sub.2 is also 4 mm.

(47) The number of turns N and the current I of the coil 6 should satisfy the following equation:

(48) $\mathrm{IN}\ge \frac{P_0{L}_{41}\left[{\left(d_0+2{\delta }_1+2\mathrm{.Math.}\right)}^2-{\left(d_0+2{\delta }_1\right)}^2\right]}{10^6\zeta {\mathrm{Bd}}_{41}}$
Where,

(49) P.sub.0—Design pressure of fluid in the pipeline, Mpa;

(50) ζ—Safety factor, 0.8˜0.9;

(51) B—Magnetic field strength in the coil 6 generated by the magnetic fluid d, A/s;

(52) I—Current in the coil 6, A;

(53) N—Number of turns of the coil 6;

(54) L.sub.41 Width of the coil 6, L.sub.41=9δ.sub.1, mm;

(55) d.sub.41 Inner diameter of the sealed end cap 5, d.sub.41=26; +d.sub.0+2ε, mm;

(56) ε—Radial clearance between the second joint pipe 4 and the sealed end cap 5, ε=0.02 d.sub.0, mm.

(57) The magnetic field strength B in the coil 6 generated by the magnetic fluid d is 10 A/s. The safety factor ζ is 0.8, d.sub.41=60 mm, L.sub.41=36 mm. The number of turns N and the current I of the coil 6 should satisfy the following equation:
IN≥3.752×10.sup.5(A)

(58) The cross-sectional width H of the annular permanent magnet 7 should satisfy the following equation:
ρ.sub.1.sup.L.sub.410HK.sub.4C.sub.4>4ρ.sub.2L.sub.411L.sub.48
Where,

(59) ρ.sub.1—Density of the annular permanent magnet 7, kg/m.sup.3;

(60) K.sub.4—Safety factor of the annular permanent magnet 7, 0.6˜0.8;

(61) H—Cross-sectional width of the annular permanent magnet 7, mm;

(62) L.sub.410—Cross-sectional length of the annular permanent magnet 7, L.sub.410=δ.sub.1, mm;

(63) L.sub.411—Cross-sectional width of the first annular liquid storage groove b, L.sub.411=δ.sub.1, mm;

(64) L.sub.48—Length of the annular permanent magnet 7, L.sub.48=1.2δ.sub.1, mm;

(65) ρ.sub.2—Density of the magnetic fluid d, kg/m.sup.3;

(66) C.sub.4—Residual magnetic coefficient of the annular permanent magnet 7.

(67) The material of the annular permanent magnet 7 is sintered NdFeB magnet, its density ρ.sub.1 is 7500 kg/m.sup.3. The material of the sealed end cap 5 is Water-based magnetic fluid MeFe.sub.2O.sub.4, its density ρ.sub.2 is 3000 kg/m.sup.3. The safety factor K.sub.4 of the annular permanent magnet is 0.6, and residual magnetic coefficient C.sub.4 of the annular permanent magnet 7 is 12; L.sub.48=4.8 mm, L.sub.410=4 mm, L.sub.411=4 mm. The cross-sectional width H of the annular permanent magnet 7 of the device should satisfy the following equation:
7500×H×0.6×4>4×3000×4×4.8

(68) which is: H>4.27 mm. H is determined to be 4.5 mm.

(69) The embodiment is a preferred embodiment of the present invention, but the present invention is not limited to the embodiment described above. Any obvious modifications, substitutions or variations that can be made by those skilled in the art are intended to be within the scope of the present invention without departing from the spirit of the present invention.