KR101254737B1 - Semi-automatical instrument deivce of permeability for wood - Google Patents

Abstract

The present invention relates to an apparatus for measuring semi-automatic permeability of wood, wherein the flow meter for measuring the air flow in a wood sample is measured in the longitudinal permeability because the flow rate is greater at the same pressure difference than in the case of the radial (radiation) direction in the longitudinal (shrinkage) direction. For a radial sample with a wide range and a low permeability radial sample, a flow meter with a small measuring range can be used to make more accurate measurements.The pressure difference across the wood sample is automatically calculated using a differential pressure gauge. , The automatic air-tight sample holding jig reduces the time required to measure permeability and ensures accurate data, maintains constant air pressure in the pressure tank, and measures the permeability Pressure to the pressure regulator and fine pressure regulation bell Given constantly maintained through more accurate and has the effect that to obtain reproducible data.

Description

Semi-automatic permeability measuring device of wood {SEMI-AUTOMATICAL INSTRUMENT DEIVCE OF PERMEABILITY FOR WOOD}

The present invention relates to a semi-automatic permeability measuring apparatus of wood, and more particularly, to a semi-automatic permeability measuring apparatus of wood for enabling more accurate and reproducible measurement of the permeability to anisotropic properties according to wood species.

 As is well known, in order to utilize wood, proper preservation treatment is required, and various wood preservation methods have been developed for this purpose.

However, the preservation process for achieving the proper degree of preservation of wood is one of the very difficult processes due to the different characteristics of wood species as well as the anisotropy of wood. It is very difficult to select a suitable antiseptic treatment process in consideration of time and the like.

On the other hand, data on the degree of preservative treatment of various treated species have generally been obtained from industrial experience and research on permeability.

However, in the past, the wood permeability measurement process has been very difficult to accurately and reproducibly measure the permeability using a decompression and manometer liquid pressure gauge.

In particular, the pressure reduction method of wood permeability measurement was very difficult to obtain the pressure difference of the liquid column pressure gauge if sufficient vacuum was not obtained. In addition, a difference occurs between the measuring device for measuring the permeability of the good permeability and the poor permeability core part is required to change the structure of the measuring device at the time of the cross measurement has a disadvantage in that the measurement time is long.

An object of the present invention for solving the above problems, to provide a semi-automatic permeability measuring device of the wood to be able to more accurately and reproducibly measure the permeability to the anisotropic properties according to the wood species.

Semi-automatic permeability measuring device of the wood of the present invention for achieving the above object is a cylindrical wood sample taken along the longitudinal or radial direction of the wood; A sample holding jig for inserting and fixing the wood sample; A sample pressing cylinder installed above the sample holding jig to press-fix the wood sample into the sample holding jig by using a pressure loader; A sample holding holder for wrapping and fixing an outer circumferential surface of the wooden sample so that the wooden sample pressurized by the sample pressing cylinder is pressed and fixed in a sealed state in the sample holding jig; An air compressor for maintaining a predetermined air pressure in the pressure tank; It is installed on the first pneumatic pipe connecting the pressure tank and the pressure loader of the sample pressure cylinder, the air supplied from the pressure tank for the permeability test of the wood sample penetrates the wood sample through the pressure loader. A sample permeation pressure regulator to regulate the air pressure to effect; Installed on a second pneumatic pipe branched on the first pneumatic pipe between the sample permeation pressure regulator and the pressure loader to connect the sample pressure cylinder to operate the sample pressure cylinder to pressurize and fix the wood sample. A sample holding pressure regulator for adjusting the air pressure of the supplied air; It is installed on the first air discharge pipe which is installed to extend the air passing through the wood sample from the sample fixing jig, and measures the amount of the first air discharged through the wood sample collected along the longitudinal direction of the wood The first flow meter to be installed on the second air discharge pipe branched from the first air discharge pipe between the sample holding jig and the first flow meter, and collected along the radial direction of the wood through the second air discharge pipe. And a second flow meter for measuring the amount of air discharged through the wood sample, wherein the first flow meter and the second flow meter are formed to have different measurement ranges, and the second flow meter is smaller than the first flow meter. It is characterized in that it is formed to have a measurement range.

Here, the sample holding jig has a circular flat cross-section is formed with a sample fixing groove so that the width becomes narrower toward the lower side, the sample fixing holder is fixed to the sample fixed groove is inserted into the sample holding groove in the state that the wooden sample is fitted It is preferably made of a hollow conical shape corresponding to the groove, and also made of a silicon material.

In addition, an air filter may be further provided on the first pneumatic pipe between the air compressor and the branch of the second pneumatic pipe to remove foreign substances and water contained in the air.

In addition, it is installed on the first pneumatic pipe between the sample permeation pressure regulator and the pressurizing loader of the sample pressurizing cylinder, the air supplied from the sample permeation pressure regulator maintains the regulated air pressure and through the pressurizing loader It may further include a sample permeation pressure control valve to be supplied to the wood sample, the sample permeation pressure control valve is preferably made of a solenoid valve.

The apparatus may further include a sample pressure gauge installed on the second pneumatic pipe connecting the sample holding pressure regulator and the sample pressing cylinder to measure the pressing force of the wood sample by the pressure loader of the sample pressing cylinder. Can be.

In addition, it is installed on the first air discharge pipe between the second air discharge pipe branch portion and the first flow meter, so as to maintain the air pressure initially caught while the air is injected into the wood sample and the first flow meter A first fine pressure control valve may be further provided to adjust the amount of discharged air discharged through it.

Further, it is provided on the second air discharge pipe between the first air discharge pipe and the second flow meter,

A second fine pressure control valve may be further provided to maintain the air pressure initially caught while the air is injected into the wood sample, and to adjust the amount of exhaust air discharged through the second flow meter.

Here, it is preferable that the measurement range of the first flow meter is within 0.01 cc / min to 500 cc / min, and the measurement range of the second flow meter is within 0.01 cc / min to 20 cc / min.

According to the semi-automatic permeability measuring apparatus of the wood of the present invention described above, since the flow meter for measuring the air flow amount in the wood sample has a greater flow rate even at the same pressure difference than in the case of the radial (radiation) direction, the longitudinal permeability is measured. The use of a flowmeter with a large measuring range and a radial sample with low permeability has the effect of making a more accurate measurement by using a flowmeter with a small measuring range.

In addition, according to the semi-automatic permeability measuring device of the wood of the present invention, the pressure difference across the wood sample is automatically calculated by using a differential pressure gauge to obtain the permeability data more easily and quickly, and the permeability using the automatic air tightening sample fixing jig In addition to reducing the time required for measurement, it has the effect of obtaining accurate data.

In addition, according to the semi-automatic permeability measuring device of the wood of the present invention, the air pressure is kept constant in the pressure tank, and the pressure in the device for measuring the permeability is kept constant through the pressure regulator and the fine pressure regulating valves for more accurate and reproducible It has the effect of getting the data you have.

1 is a schematic diagram showing a semi-automatic permeability measuring apparatus of wood according to an embodiment of the present invention.
Figure 2 is a schematic diagram showing the operating state of the sample holding holder of the wood of the semi-automatic permeability measuring device of the wood of FIG.
3 (a) and 3 (b) are photographs showing a longitudinally collected wood sample and a radially collected sample used in the semi-automatic permeability measuring apparatus of wood.
4 is a schematic diagram for explaining a theoretical background for measuring the permeability of a wood sample.
5 is a diagram showing the longitudinal and radial permeability of the hardwoods measured using the semi-automatic permeability measuring device of the wood of the present embodiment.
FIG. 6 is a graph illustrating longitudinal permeability according to the type of hardwood tree of FIG. 5.
FIG. 7 is a graph illustrating longitudinal permeability according to the types of hardwoods of FIG. 5.
8 is a diagram showing the longitudinal and radial permeability of the softwoods measured using the semi-automatic permeability measuring device of the wood of the present embodiment.
FIG. 9 is a graph illustrating longitudinal permeability according to the type of coniferous tree of FIG. 8.
FIG. 10 is a graph illustrating longitudinal permeability according to the type of hardwoods of FIG. 8.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and the same or similar components are denoted by the same reference numerals throughout the specification.

1 is a schematic view showing a semi-automatic permeability measuring apparatus of wood according to an embodiment of the present invention, Figure 2 is a schematic diagram showing the operating state of the sample holder of the wood of the semi-automatic permeability measuring apparatus of the wood of FIG.

Referring to FIGS. 1 and 2, the semi-automatic permeability measuring apparatus 1 of wood in this embodiment is essentially a sample holding jig 20, a sample pressurizing cylinder 30, a sample holding holder 40, and an air compressor. It comprises a 50, the sample permeation pressure regulator 70, the sample fixed pressure regulator 80, the 1st flowmeter 90, and the 2nd flowmeter 100. As shown in FIG.

The sample fixing jig 20 is provided with a sample fixing groove 21 to fix the wood sample 10.

In this embodiment, the wood sample 10 exemplifies a cylindrical sample taken along the longitudinal or radial direction of the wood for permeability test.

3 (a) and 3 (b) are photographs showing a longitudinally collected wood sample and a radially collected sample used in the semi-automatic permeability measuring apparatus of wood.

Referring to FIG. 3, the preparation of the wood sample 10 for the permeability test is taken in a cylindrical shape using a press drill equipped with a plug cutter having an inner diameter of 12 mm, and the collected wood sample (10) are finally stored in the place where permeability is to be measured and allowed to air.

Further, the length of the wood sample 10 is 30 mm in the longitudinal direction, that is, the wood sample 10a for measuring the permeability in the longitudinal direction, and 20 mm in the radial direction, that is, the wood sample 10b for measuring the permeability in the radial direction. Both ends are cut as much as possible so that this cutting surface is perpendicular to the direction of air flow during the permeability measurement.

1 and 2, the sample holding groove 21 of the sample holding jig 20 is pressurized in a state in which the wooden sample 10 is fitted into a sample holding holder 40 which will be described later. It is preferably formed to have a narrow width toward the lower side with a circular flat cross-section to be pressed by the cylinder 30 and pressed fixed in a closed state.

The sample pressurizing cylinder 30 is installed above the sample holding jig 20 by using the pressurized air to maintain the pressure established by the air compressor 60, and then presses the wood sample 10 with the press loader 31. It is configured to press-fix the inside of the sample fixing groove 21 of the sample fixing jig 20.

The sample holding holder 40 wraps the outer circumferential surface of the wooden sample 10 such that the wooden sample 10 pressurized by the sample pressing cylinder 30 is pressed and fixed in a sealed state in the sample holding jig 20. Configured to lock.

In the present embodiment, the sample holding holder 40 has a hollow conical end shape corresponding to the sample holding groove 21 so that the sample holding groove 21 is fitted into the sample holding groove 21 while being pressed into the wood sample 10. Illustrates what is formed of a silicon material with.

The air compressor 60 serves to pressurize and supply air to maintain a predetermined air pressure in the pressure tank 10.

In this embodiment, the pressure tank 50 is made of a stainless material having a capacity of approximately 10L, and illustrates that the air pressure in the pressure tank 50 maintained by the air compressor 60 is 3 kgf / cm ² .

On the other hand, the air filter 160 for removing the foreign matter and water contained in the air supplied from the pressure tank 50 to the sample permeation pressure regulator 70 or the sample fixed pressure regulator 80 is preferably further provided. .

The sample permeation pressure regulator 70 is installed on the first pneumatic pipe 210 connecting the pressure tank 50 and the pressure loader 31 of the sample pressure cylinder 30 to provide the wood sample 10. The air pressure is adjusted such that the air supplied from the pressure tank 50 penetrates the wood sample 10 through the pressure loader 31 for the permeability test.

In the present embodiment, the sample permeation pressure regulator 70 is composed of a digital pressure regulator, which is 0.01 kg _f / cm ² to 3 kg _f / cm ² It illustrates that it is configured to be adjustable within the pressure range.

On the other hand, it is preferable that the permeation pressure control valve 110 is further provided on the first pneumatic pipe 210 between the sample permeation pressure regulator 70 and the pressurization loader 31 of the sample pressure cylinder 30. Do.

The permeation pressure regulating valve 110 serves to adjust the permeation of the wood sample through the pressure loader 31 by constantly walking the supplied air pressure controlled by the sample permeation pressure regulator 70. Here, the permeation pressure control valve 110 is preferably made of a solenoid valve.

The sample holding pressure regulator 80 is branched on the first pneumatic pipe 210 between the pressure tank 50 and the sample permeation pressure and on the second pneumatic pipe 220 connecting the sample pressurizing cylinder 30. Is installed in, is configured to adjust the pressure of the air for operating the sample pressure cylinder 30 to pressure-fix the wood sample 10.

In the present embodiment, the sample holding pressure regulator 80 is made of a digital pressure regulator similar to the above sample permeation pressure regulator, and the sample holding cylinder 30 is within the range of 5 kg _f / cm ² to 6 kg _f / cm ² . Illustrates to adjust the pressure range of air which is the movable fluid supplied.

In addition, a sample pressure gauge 120 may be further installed on the second pneumatic pipe 220 connecting the sample fixed pressure regulator 80 and the sample pressure cylinder 30.

The sample pressure gauge 120 to measure the pressing force of the wood sample 10 by the pressure loader 31 of the sample pressure cylinder 30.

The first flow meter 100 is installed on the first air discharge pipe 230 extending to discharge the air that has passed through the wood sample 10 from the sample fixing jig 20, It is configured to measure the air flow rate discharged after passing through the wood sample (10 (a)) taken along the longitudinal direction.

The second flow meter 90 is installed on the second air discharge pipe 240 branched on the first air discharge pipe 230 between the sample fixing jig 20 and the first flow meter 100. It is configured to measure the amount of air discharged through the wood sample (10 (b)) taken along the radial direction of the wood through the second air discharge pipe 240.

Here, the first flow meter 100 and the second flow meter 90 is formed to have a different measurement range, the second flow meter 90 is formed to have a smaller measurement range than the first flow meter 100 It is preferable to be.

In the present embodiment, the measurement range of the first flow meter 100 is within 0.01 cc / min to 500 cc / min, and the measurement range of the second flow meter 90 is within 0.01 cc / min to 20 cc / min. do.

In addition, the first air discharge pipe 230 and the second air discharge pipe 240 to maintain a constant air pressure initially set for the permeability test of the wood sample 10 as well as the first and First and second fine pressure regulating valves 130 and 140 are installed to adjust the amount of air discharged through the second flow meters 90 and 100.

The first fine pressure control valve 140 is installed on the first air discharge pipe 230 between the second air discharge pipe 240 branch and the first flow meter 100, the first fine pressure control The valve 130 is installed on the second air discharge pipe 240 between the branch of the second air discharge pipe 240 and the second flow meter 90.

Then, the differential pressure gauge 150 is installed on the connecting pipe 250 to measure the pressure difference across the wood sample 10 so that the pressure difference between them is automatically calculated.

Hereinafter, the longitudinal and radial permeability measuring process of the wood using the semi-automatic permeability measuring device 1 of the wood will be described.

4 is a schematic diagram for explaining a theoretical background for measuring the permeability of a wood sample.

Referring to FIG. 4, the measurement of permeability to the wood sample 10 is defined as the flow rate per unit area with respect to the pressure gradient by Darcy's law.

Fluid flow through porous solids such as wood is directly proportional to the pressure gradient and the permeability of wood.

Therefore, the permeability of the wood sample can be obtained through Equation 1 below.

Where K is permeability (darcy, cm ² -cp / sec-atm), Q is flow rate (cc / min), P 'is the pressure applied to the wood sample ((P1 + P2) / 2), and Pa is Atmospheric pressure, ΔP is the pressure difference across the wood sample (P1-P2), u is the viscosity of nitrogen (0.0178 cps), A is the cross-sectional area of the wood sample (cm ² ), and L is the length of the wood sample .

Therefore, the permeability measurement process of the wood sample using the semi-automatic permeability measuring device 1 of the wood of the present embodiment described above, first, the air pressure in the pressure tank 50 by using the air compressor 60 maintains 3kg _f / cm ² Do it.

After fixing the sample holding holder 40 made of silicon material on the outside of the wood sample 10 collected as shown in FIG. 3, the sample holding holder 21 is inserted into the sample holding groove 21 of the sample holding jig 20 and the sample holding pressure regulator 80. By supplying a pressure-controlled air to the sample pressure cylinder 30 using the pressure loader 31 to pressurize the wood sample 10 to be fixed in the sample fixing groove 31.

The internal pressure of the device for measuring the permeability of the wood sample 10 is kept constant at 2kg _f / cm ² using the permeation pressure regulating pressure valve 110, the pressure difference across the wood sample 10 is the differential pressure gauge ( 150) to be automatically calculated.

By adjusting the amount of air introduced by adjusting the first and second fine pressure control valve (130, 140) to prevent the air pressure initially caught while the air of the predetermined pressure is injected into the wood sample (10) The pressure was controlled.

Since the flow meter for measuring the air flow amount in the wood sample 10 has a large flow rate in the longitudinal direction even at the same pressure difference than the radial direction, the first flow meter 100 having a large measuring range in the longitudinal permeability is used, and the low permeability radial direction is used. Permeability is to be measured using a second flow meter (90) having a small measurement range.

Hereinafter, the results of measuring the longitudinal and radial permeability of each species of hardwoods using the semi-automatic permeability measuring apparatus of the wood according to the present embodiment through FIGS. 5 to 7 will be described.

5 is a diagram showing the longitudinal and radial permeability of the hardwoods measured using the semi-automatic permeability measuring device of the wood of the present embodiment, Figure 6 is a comparison of the longitudinal permeability according to the type of hardwoods of FIG. FIG. 7 is a graph illustrating longitudinal permeability according to the type of broadleaf tree of FIG. 4.

Referring to FIGS. 5 to 7, the permeability measurement results for each hardwood tree were measured to be at least about 20 to 4,500 times higher than the radial permeability.

In the case of longitudinal permeability, Dellenia-2 was found to be the largest at 6.123 Darcy, followed by Apitong-1 at 5.420 Darcy. White oak and Burckella showed low permeability of 0.015 and 0.008 Darcy. The permeability of Calophyllum, Malas and Kempas was 0.999 ~ 1.380.

In the case of radial permeability, it was 0.0004 ~ 0.0053, which is very small compared to the longitudinal permeability, and the difference between species was also lower than the longitudinal permeability.

Dellenia species were also found to have the highest radial permeability. Wood, an anisotropic material, shows a clear difference in flow rate according to the flow direction, and the longitudinal flow is much larger than the tangential direction or the radial direction.

The results of measuring the longitudinal and radial permeability of each species of coniferous wood using the semi-automatic permeability measuring device of the wood according to the present embodiment through FIGS. 8 to 10 are as follows.

8 is a diagram showing the longitudinal and radial permeability of the coniferous trees measured by the semi-automatic permeability measuring device of the wood of the present embodiment, Figure 9 is a comparison of the longitudinal permeability according to the type of coniferous wood of Figure 8 FIG. 10 is a graph illustrating longitudinal permeability according to the type of broadleaf tree of FIG. 8.

Referring to FIGS. 8 to 10, the permeability measurement results for each conifer tree were measured to be at least about 7 to 190 times higher than the radial permeability.

The difference in the permeability of conifers by direction was much smaller than that of hardwoods. For longitudinal permeability, the Hemlock was found to be the largest at 0.368 Darcy.

 The most permeable of hardwoods is 1/16 compared to Dellenia-2, which is the effect of large conduits. Alaska hemlock, Spruce and Larch were low permeability (0.013 ~ 0.053 Darcy). Longitudinal permeability of red pine, red cedar and Douglas-fir was measured from 0.101 to 0.194

The radial permeability was 0.0004 ~ 0.013, which was lower than the longitudinal permeability, and the difference in species permeability was lower than the longitudinal permeability. .

As described above, the semi-automatic permeability measuring device of the wood of the present embodiment has a flowmeter for measuring the air flow in the wood sample, so the longitudinal permeability is greater because the flow rate is greater at the same pressure difference than in the case of the radial (radiation) direction. Larger flowmeters and lower permeable radial samples can be used with smaller flowmeters for more accurate measurements.

In addition, the pressure difference across the wood sample can be automatically calculated using a differential pressure gauge to make the permeability data easier and faster.The automatic air-tight sample fixing jig reduces the time required for permeability measurement and provides accurate data. Make sure

In addition, the air pressure is kept constant in the pressure tank, and the pressure in the device for measuring permeability is kept constant through the pressure regulator and the fine pressure regulating valves to obtain more accurate and reproducible data.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and various modifications or changes can be made within the scope of the claims and the detailed description of the invention and the accompanying drawings. In addition, it is natural that it belongs to the scope of the present invention.

1: Permeability measuring device 10: Wood sample
20: sample holding jig 21: sample holding groove
30: sample pressurized cylinder 31: pressurized loader
40: sample holding holder 50: pressure tank
60: air compressor 70: sample permeation pressure regulator
80: sample fixed pressure regulator 90: second flow meter
100: first flow meter 110: permeation pressure regulating valve
120: sample pressure gauge 130: second fine pressure control valve
140: first fine pressure regulating valve 150: differential pressure gauge
160: air filter 210: first pneumatic pipe
220: second pneumatic pipe 230: second air discharge pipe
240: first air exhaust pipe

Claims (10)

Cylindrical wood samples taken along the longitudinal or radial direction of the wood;
A sample holding jig for inserting and fixing the wood sample;
A sample pressing cylinder installed above the sample holding jig to press-fix the wood sample into the sample holding jig by using a pressure loader;
A sample holding holder for wrapping and fixing an outer circumferential surface of the wooden sample so that the wooden sample pressurized by the sample pressing cylinder is pressed and fixed in a sealed state in the sample holding jig;
An air compressor for maintaining a predetermined air pressure in the pressure tank;
It is installed on the first pneumatic pipe connecting the pressure tank and the pressure loader of the sample pressure cylinder, the air supplied from the pressure tank for the permeability test of the wood sample penetrates the wood sample through the pressure loader. A sample permeation pressure regulator to regulate the air pressure to effect;
Installed on a second pneumatic pipe branched on the first pneumatic pipe between the sample permeation pressure regulator and the pressure loader to connect the sample pressure cylinder to operate the sample pressure cylinder to pressurize and fix the wood sample. A sample holding pressure regulator for adjusting the air pressure of the supplied air;
It is installed on the first air discharge pipe which is installed to extend the air passing through the wood sample from the sample fixing jig, and measures the amount of the first air discharged through the wood sample collected along the longitudinal direction of the wood 1st flow meter:
Is installed on the second air discharge pipe branched from the first air discharge pipe between the sample holding jig and the first flow meter, through the wood sample taken along the radial direction of the wood through the second air discharge pipe It includes; a second flow meter for measuring the amount of air discharged,

The first flow meter and the second flow meter are formed to have a different measurement range,
Semi-automatic permeability measuring apparatus of wood, wherein the second flow meter is formed to have a smaller measuring range than the first flow meter.
In claim 1,
The sample holding jig has a circular flat cross section is formed with a sample fixing groove to be narrower toward the lower side,
The sample holding holder is a semi-automatic permeability measuring device of the wood made in the shape of a hollow conical end corresponding to the sample holding groove to be fitted into the sample holding groove in the state in which the wooden sample is fitted.
In claim 2,
The sample holder is a semi-automatic permeability measuring device of wood made of a silicon material.
In claim 1,
Is provided on the first pneumatic pipe between the air compressor and the branch of the second pneumatic pipe,
Semi-automatic permeability measuring device of wood further comprises an air filter to remove foreign matter and moisture contained in the air.
5. The method of claim 4,
Is installed on the first pneumatic pipe between the pressure tank and the sample permeation pressure regulator,
And a sample permeation pressure control valve for maintaining the air pressure supplied from the sample permeation pressure regulator and supplying the wood sample through the pressure loader.

The method of claim 5,
The sample permeation pressure control valve is a semi-automatic permeability measuring device of wood consisting of a solenoid valve.
The method of claim 5,
Is installed on the second pneumatic pipe connecting between the sample fixed pressure regulator and the sample pressure cylinder,
Semi-automatic permeability measuring device of the wood is further provided with a sample pressure gauge for measuring the pressing force of the wood sample by the pressure loader of the sample pressure cylinder.
In claim 7,
Is installed on the first air discharge pipe between the second air discharge pipe branch and the first flow meter,
Semi-automatic wood is further provided with a first fine pressure regulating valve for adjusting the air pressure is injected into the wood sample to maintain the initially caught air pressure and to measure the amount of exhaust air discharged through the first flow meter Permeability measuring device.
9. The method of claim 8,
Is installed on the second air discharge pipe between the first air discharge pipe and the second flow meter,
Semi-automatic wood is further provided with a second micro-pressure control valve for adjusting the air pressure is initially injected while the air is injected into the wood sample and to measure the amount of exhaust air discharged through the second flow meter Permeability measuring device.
The method of claim 9,
The measuring range of the first flow meter is within 0.01 cc / min to 500 cc / min,
Measuring range of the second flow meter is a semi-automatic permeability measuring apparatus of wood, including that within 0.01cc / min to 20cc / min.

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