Testing apparatus for gas permeability in concrete and testing method therefor

Abstract

An apparatus and method for testing gas permeability in concrete are provided. The apparatus is used for testing gas permeability of a concrete test sample, and includes a gas supply apparatus, an instrument body and a gas flow meter. The instrument body includes a frame body. A gas inlet ring, a gas outlet ring and a connection plate are successively arranged on the frame body from inside to outside. An input end of the gas inlet ring is connected with the gas supply apparatus, and an output end is connected with an input end of the gas outlet ring through the concrete test sample. An output end of the gas outlet ring is connected with the gas flow meter. The connection plate is connected with the concrete test sample.

Claims

1. An apparatus for testing gas permeability in concrete, which is used for testing gas permeability of a concrete test sample (1), comprising: a gas supply apparatus (2), an instrument body (3), and a gas flow meter (4), wherein the instrument body (3) comprises a frame body (36); a gas inlet ring (31), a gas outlet (32) and a connection plate (33) are successively arranged on the frame body (36) from inside to outside; an input end of the gas inlet ring (31) is connected with the gas supply apparatus (2); an output end is connected with an input end of the gas outlet ring (32) through the concrete test sample (1); the output end of the gas outlet ring (32) is connected with the gas flow meter (4); and the connection plate (33) is connected with the concrete test sample (1); and the gas supply apparatus (2) supplies test gas of constant gas pressure to the instrument body (3); the test gas flows to the gas flow meter (4) from the gas inlet ring (31) successively via the concrete test sample (1) and the gas outlet ring (31); and then a gas permeability coefficient of the concrete is calculated according to a gas flow.

2. The apparatus for testing gas permeability in concrete according to claim 1, wherein a bottom surface of the gas inlet ring (31) is circular; a bottom surface of the gas outlet ring (32) has a shape of a circular ring; and a bottom area of the gas inlet ring (31) is the same as the bottom area of the gas outlet ring (32).

3. The apparatus for testing gas permeability in concrete according to claim 1, wherein an inner sealing ring (34) is arranged between the gas inlet ring (31) and the gas outlet ring (32), and an outer sealing ring (35) is arranged between the gas outlet ring (32) and the connection plate (33).

4. The apparatus for testing gas permeability in concrete according to claim 3, wherein the gas supply apparatus (2) comprises a gas source (21), and a first gas transport channel (22), a second gas transport channel (23) and a third gas transport channel (24) with input ends being respectively connected with the gas source (21); an output end of the first gas transport channel (22) is connected with the input end of the gas inlet ring (31); an output end of the second gas transport channel (23) is connected with the input end of the inner sealing ring (34); and the output end of the third gas transport channel (24) is connected with the input end of the outer sealing ring (35).

5. The apparatus for testing gas permeability in concrete according to claim 4, wherein a test gas dehumidification apparatus (221) is arranged on the first gas transport pipe (22).

6. The apparatus for testing gas permeability in concrete according to claim 4, wherein the gas source (21) comprises a relief valve (211), and a precision relief valve (222) is arranged on the first gas transport pipe (22).

7. The apparatus for testing gas permeability in concrete according to claim wherein the instrument body (3) further comprises a plurality of fixing screw rods (37), and the connection plate (33) is connected with the concrete test sample (1) through the fixing screw rods (37).

8. A test method of the apparatus for testing gas permeability in concrete according to claim 1, comprising the steps: A, fixing an instrument body (3) to a structural concrete test sample (1) reaching maturity, and inflating an inner sealing ring (34) and an outer sealing ring (35) until the internal pressure reaches 6 to 7 atmospheric pressures; B, introducing test gas with the gas pressure constant at the test gas pressure into the gas inlet ring (31), recording a gas flow permeating the concrete test sample (1) after the gas flow is stabilized, and calculating a permeability coefficient: $D=\frac{2\mathrm{QL}\mathrm{Pa}}{A\left(P^2-{\mathrm{Pa}}^2\right)}$ wherein is the permeability coefficient, L is an effective permeation thickness, Q is gas flow, u is gas viscosity, Pa is local atmospheric pressure, A is permeable area, and P is the test gas pressure; and C, changing the test gas pressure, repeating the step B for three to five times, and calculating an average value of multiple measured permeability coefficients as a test value of the concrete test sample (1).

9. The test method according to claim 8, wherein an effective permeation thickness L is: $L=\frac{\sqrt{2}}{2}\sqrt{R_3^2+R_2^2}-\frac{\sqrt{2}}{2}{R}_1$ wherein R.sub.7 is a radius of a bottom surface of the gas inlet ring, R.sub.2 is a radius of an inner circle of a bottom surface of the gas outlet ring, and R.sub.3 is a radius of an outer circle of the bottom surface of the gas outlet ring.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is structural schematic diagram of the present invention;

(2) FIG. 2 is a schematic bottom view of an instrument body in embodiment 1 of the present invention;

(3) FIG. 3 is a schematic sectional view of an instrument body in embodiment 1 of t he present invention;

(4) FIG. 4 is a structural schematic diagram of an inner sealing ring in embodiment 1 of the present invention;

(5) FIG. 5 is a three-dimensional schematic sectional view of an inner sealing ring in embodiment 1 of the present invention;

(6) FIG. 6 is a schematic diagram of a motion path of test gas on a surface layer of a concrete test sample;

(7) FIG. 7 is a structural schematic diagram of an instrument body in embodiment 2 of the present invention; and

(8) FIG. 8 is a schematic diagram of a permeation thickness calculation process.

(9) In the figures: 1: concrete test sample; 3: instrument body; 4: gas flow meter; 25: diversion section; 26: diversion section; 211: relief valve; 212: liquid nitrogen cylinder tightening valve; 213: plastic connection hose; 214: liquid nitrogen cylinder; 215: gas filter; 216: safety valve; 221: test gas dehumidification apparatus; 222: precision relief valve; 223: stop-check valve; 224: stop-check valve; 225: diversion section; 231: stop-check valve; 241: stop-check valve; 31: gas inlet ring; 32: gas outlet ring; 33: connection plate; 34: inner sealing ring; 35: outer sealing ring; 36: frame body; 37: fixing screw rod; 38: gas inlet hole; 39: gas outlet hole; 341: gas inlet pipe of inner sealing ring; and 351: gas inlet pipe of outer sealing ring.

DETAILED DESCRIPTION OF THE EMBODIMENTS

(10) The present invention is further described below in detail in combination with drawings and specific embodiments. The present embodiment is implemented on the premise of a technical solution of the present invention and gives detailed embodiments and a specific operation process, but the protection scope of the present invention is not limited to embodiments described below.

Embodiment 1

(11) An apparatus for testing gas permeability in concrete is used for testing gas permeability of a concrete test sample 1. As shown in FIG. 1, the apparatus for testing gas permeability in concrete includes a gas supply apparatus, an instrument body 3 and a gas flow meter 4. As shown in FIG. 2 and FIG. 3, the instrument body 3 includes a frame body 36. A gas inlet ring 31, a gas outlet ring 32 and a connection plate 33 are successively arranged on the frame body 36 from inside to outside. The input end of the gas inlet ring 31 is connected with the gas supply apparatus 2, and the output end is connected with the input end of the gas outlet ring 32 through the concrete test sample 1. The output end of the gas outlet ring 32 is connected with the gas flow meter 4. The connection plate 33 is connected with the concrete test sample 1, wherein in the present embodiment, the gas flow meter 4 is a soap film flow meter.

(12) The gas supply apparatus 2 supplies test gas to the instrument body 3. The test gas flows to the gas flow meter 4 from the gas inlet ring 31 successively via the concrete test sample 1 and the gas outlet ring 32, so that the concrete gas permeability coefficient is calculated according to the gas flow.

(13) An inner sealing ring 34 is arranged between the gas inlet ring 31 and the gas outlet ring 32, and an outer sealing ring 35 is arranged between the gas outlet ring 32 and the connection plate 33.

(14) As shown in FIG. 2, the inner sealing ring 34 is arranged between the gas inlet ring 31 and the gas outlet ring 32, and the outer sealing ring 35 is arranged between the gas outlet ring 32 and the connection plate 33.

(15) The gas supply apparatus 2 includes a gas source 21, and a first gas transport channel 22, a second gas transport channel 23 and a third gas transport channel 24 with input ends being respectively connected with the gas source 21. The output end of the first gas transport channel 22 is connected with the input end of the gas inlet ring 31; the output end of the second gas transport channel 23 is connected with the input end of the inner sealing ring 34; and the output end of the third gas transport channel 24 is connected with the input end of the outer sealing ring 35.

(16) As shown in FIG. 1 and FIG. 2, a gas inlet hole 38 is formed in the center of the gas inlet ring 31; a gas outlet hole 39 is formed in the gas outlet ring 32; the first gas transport channel 22 is connected with the gas inlet ring 31 through the gas inlet hole 38; and the gas flow meter 4 is connected with the gas outlet ring 32 through the gas outlet hole 39.

(17) As shown in FIG. 1, FIG. 4 and FIG. 5, a gas inlet pipe 341 of inner sealing ring is arranged on the inner sealing ring 34, and the second gas transport channel 23 is connected with the inner sealing ring 34 through the gas inlet pipe 341 of the inner sealing ring; and the structure of the outer sealing ring 35 is similar to that of the inner sealing ring 34. As shown in FIG. 1, the third gas transport channel 24 is connected with the outer sealing ring 35 through a gas inlet pipe 351 of outer sealing ring.

(18) A test gas dehumidification apparatus 221 is arranged on a first gas transport pipe 22.

(19) The gas source 21 includes a relief valve 211, and a precision relief valve 222 is arranged on the first gas transport pipe 22.

(20) The instrument body 3 also includes a plurality of fixing screw rods 37. The connection plate 33 is connected with the concrete test sample 1 through the fixing screw rods 37. A plurality of screw holes for the fixing screw rods 37 to pass through are formed in the connection plate 33. The quantity of the screw holes is consistent with the quantity of the fixing screw rods 37. In the present embodiment, the quantity of the fixing screw rods 37 and the quantity of the screw holes are respectively 6.

(21) As shown in FIG. 1, in the present embodiment, the gas source 21 also includes a liquid nitrogen cylinder 214, a plastic connection hose 213, a liquid nitrogen cylinder tightening valve 212, a gas filter 215 and a safety valve 216. The liquid nitrogen cylinder 214, the plastic connection hose 213, the liquid nitrogen cylinder tightening valve 212, the relief valve 211, the gas filter 215 and the safety valve 216 are successively connected.

(22) As shown in FIG. 1, the first gas transport channel 22 also includes two stop-check valves 223 and 224 as well as a diversion section 225, the stop-check valve 223, the precision relief valve 222, the diversion section 225 and the test gas dehumidification apparatus 221 are successively connected, the test gas dehumidification apparatus 221 is connected with the gas inlet hole 38, and the diversion section 225 is connected with the check-stop valve 224.

(23) As shown in FIG. 1, the second gas transport channel 23 includes a stop-check valve 231. The third gas transport channel 24 includes a stop-check valve 241. The gas supply apparatus 2 also includes two diversion sections 25 and 26. The input end of the diversion section 25 is connected with the gas source 21. One output end of the diversion section 25 is connected with the stop-check valve 223, and the other output end of the diversion section 25 is connected with the input end of the diversion section 26. The input end of the diversion section 26 is correspondingly connected with the stop-check valve 231 and the stop-check valve 241 respectively.

(24) The above apparatus for testing gas permeability in concrete is used for testing different concrete test samples 1 shown in Table 1.

(25) TABLE-US-00001 TABLE 1 Mixing proportion of concrete for test Mixing proportion/kg Water- Water Test cement reducing f.sub.c,28d/ No. ratio Water Cement Sand Stone agent MPa 1 0.58 212 365 691 1129 29.4 2 0.55 201 365 675 1150 34.5 3 0.52 190 365 609 1236 36.6 4 0.42 152 365 609 1236 3.65 42.9

(26) The test specifically includes the following steps:

(27) A, closing all stop-check valves as well as a relief valve 211, a precision relief valve 222, a liquid nitrogen cylinder tightening valve 212 and a safety valve 216; drilling six holes in a concrete test sample 1 reaching maturity by using a percussion drill according to positions of screw holes of an instrument body 3; burying fixing screw rods 37 into the concrete by utilizing a quick-hardening binder; aligning the instrument body 3 with the screw rods; and tightening screw caps to allow the instrument body 3 to tightly contact the concrete test sample 1; and during test, firstly opening the stop-check valve 231 and the stop-check valve 241, then opening the liquid nitrogen cylinder tightening valve 212 and the relief valve 211, and adjusting the relief valve 211 to inflate the inner sealing ring 34 and the outer sealing ring 35 until the internal pressure reaches 6 to 7 atmospheric pressures;

(28) B, closing the stop-check valve 231 and the stop-check valve 241, opening the stop-check valve 223 and the test gas dehumidification apparatus 221, adjusting the precision relief valve 222 to enable the pressure of the test gas entering the instrument body 3 to be 0.1 MPa, recording, by a gas flow meter 4, the gas flow permeating the concrete test sample 1 after the gas flow is stabilized, and calculating the permeability coefficient:

(29) $D=\frac{2\mathrm{QL}\mathrm{Pa}}{A\left(P^2-{\mathrm{Pa}}^2\right)}$

(30) wherein D is the permeability coefficient, L is an effective permeation thickness, Q is the gas flow, u is gas viscosity, Pa is a local atmospheric pressure, A is permeable area, and P is test gas pressure; and

(31) the effective permeation thickness L is:

(32) $L=\frac{\sqrt{2}}{2}\sqrt{R_3^2+R_2^2}-\frac{\sqrt{2}}{2}{R}_1$

(33) wherein R.sub.1 is a radius of a bottom surface of the gas inlet ring, R.sub.2 is a radius of an inner circle of a bottom surface of the gas outlet ring, and R.sub.3 is a radius of an outer circle of the bottom surface of the gas outlet ring.

(34) Specifically, L=L.sub.1+.sub.2+L.sub.3

(35) As shown in FIG. 6 and FIG. 8: R.sub.1 is the radius of the bottom surface of the gas inlet ring 31, R.sub.2 is the radius of the inner circle 32-1 of the bottom surface of the gas outlet ring, R.sub.3 is the radius of the outer circle 32-2 of the bottom surface of the gas outlet ring. In the present embodiment, R.sub.1 is 50 mm, R.sub.2 is 100 mm, R.sub.3 is 112 mm. The permeation of the gas from the gas inlet ring 31 can be equivalent to the permeation from a circumference of a circle A. The circle A is concentric with the gas inlet ring 31, and an area is equal to half of the gas inlet area 31. Similarly, the permeation of the gas from the gas outlet ring 32 can be equivalent to the permeation from the circumference of the circle B, and the area of the gas inlet ring 32 is equally divided by the circle B. L.sub.1 is a difference between the radius R.sub.1 of the gas inlet ring 31 and the radius R.sub.A of the circle A, and a calculation process is as follows:

(36) $L_1=\left(1-\frac{\sqrt{2}}{2}\right)R_1$

(37) L.sub.2 is a thickness of the sealing ring. A calculation process is L.sub.2=R.sub.2R.sub.1. L.sub.3 is a difference between the radius R.sub.B of the circle B and the radius R.sub.2 of the inner circle of the bottom surface of the gas outlet ring. The calculation process is:

(38) $L_3=\frac{\sqrt{2}}{2}\sqrt{R_3^2+R_2^2}-R_2$

(39) When the quantity of the gas permeated from the interior of the concrete test sample 1 is greater than 90% of the quantity of the gas entering the concrete test sample 1 (under the condition that an error is 10%), the test data is considered to be valid.

(40) C, Changing the test gas pressure to be 0.2 MPa and 0.3 MPa respectively, repeating the step B, and measuring the gas flow under various conditions. The test data is shown in Table 2.

(41) TABLE-US-00002 TABLE 2 Summary of concrete permeating gas flow rates Unit: ml/min Water- Test cement Test gas pressure P (MPa) No. ratio P = 0.1 P = 0.2 P = 0.3 1 0.58 171.4 447.8 900.8 2 0.55 123.2 324.3 618.6 3 0.52 59 155.4 300 4 0.42 16.4 39.7 73

(42) The gas permeability coefficient values of the tested sample under the permeation pressure of 0.1 MPa, 0.2 MPa and 0.3 MPa are obtained; and a test result is shown in Table 3.

(43) TABLE-US-00003 TABLE 3 Summary of concrete permeabflity coefficient results Unit: 10.sup.15 m.sup.2 Water- Test cement P = 0.1 P = 0.2 P = 0.3 Average No. ratio MPa MPa MPa value 1 0.58 3.15 3.09 3.31 3.18 2 0.55 2.27 2.24 2.28 2.26 3 0.52 1.09 1.07 1.10 1.09 4 0.42 0.30 0.27 0.27 0.28

(44) An average value of multiple obtained permeability coefficients is calculated as a test value of the concrete test sample 1.

Embodiment 2

(45) Similarities in the present embodiment to embodiment are not repeated herein, and only the difference is described.

(46) The present embodiment significantly differs from embodiment 2 in the shape of the connection plate 33. As shown in FIG. 7, in the present embodiment, bulges for connecting hoops are arranged on both sides of the connection plate 33. In the case that the concrete test samples 1 are a beam and a column, the instrument body 3 of the present embodiment is used and fixed by virtue of the hoops.