CN212505037U - Vacuum furnace carbon potential dynamic detection device - Google Patents

Abstract

The utility model relates to a vacuum furnace carbon potential dynamic verification technical field discloses a vacuum furnace carbon potential dynamic verification device, and it is including the admission pipe, carbon permeation tube and the discharge pipe that communicate in proper order, and the carbon permeation tube is located the furnace of vacuum furnace, is equipped with first mass flow on the admission pipe and detects the piece and be used for heating the heating member that the interior mark gas of admission pipe, is equipped with second mass flow on the discharge pipe and detects piece and vacuum pump. The utility model discloses a vacuum furnace carbon potential dynamic detection device is through placing the carbon permeability tube in the furnace of vacuum furnace to detect the piece real-time detection through first mass flow and second mass flow and pass through the carbon content in furnace infiltration carbon permeability tube, thereby calculate the carbon potential in the vacuum furnace, be convenient for the carbon potential in the furnace of real-time detection vacuum furnace, and adjust furnace's carbon potential according to actual need, the qualification rate of part has been improved, the probability that the carbon black appears in the part rear surface of being heated has been reduced.

Description

Vacuum furnace carbon potential dynamic detection device

Technical Field

The utility model relates to a vacuum furnace carbon potential dynamic detection technical field especially relates to a vacuum furnace carbon potential dynamic detection dress.

Background

The vacuum heat treatment has the characteristics of high efficiency, energy conservation and greenness, is a main popularization mode of enterprise transformation upgrading, is one of key technologies for improving the surface hardness, fatigue strength, abrasion strength and service life of mechanical parts, is widely applied to surface hardening treatment of key components such as gears, bearings and the like, and plays an important role in upgrading and upgrading industrial products.

Vacuum low-pressure carburization has a plurality of technical advantages, but dynamic monitoring of carbon potential in the heat treatment process cannot be realized, and a vacuum carburized product can only determine whether a workpiece meets the process requirements by detecting the workpiece or a sample after being discharged, namely, the part can only be detected finally, but dynamic change of the carbon potential cannot be detected. The main method for supplying carbon to the parts at the present stage is to simulate the carbon introduced into the furnace at each stage in advance to determine the introduction amount and introduction time of the atmosphere, so that whether the parts in different batches are qualified or not can be determined only by tests, the process universality is poor, the parts are unqualified, and the surface of the parts is subjected to carbon black after being heated, so that the popularization and the application of the vacuum low-pressure carburization technology are hindered.

SUMMERY OF THE UTILITY MODEL

Based on above, an object of the utility model is to provide a vacuum furnace carbon potential dynamic verification device, the part percent of pass that has solved prior art existence is low with the part problem that carbon black appears in the rear surface of being heated.

In order to achieve the purpose, the utility model adopts the following technical proposal:

the utility model discloses a vacuum furnace carbon potential dynamic detection device, including admission pipe, carbon infiltration pipe and the discharge pipe that communicates in proper order, the carbon infiltration pipe is located the furnace of vacuum furnace, be equipped with first mass flow on the admission pipe and detect the piece and be used for the heating member of the interior mark gas of admission pipe, be equipped with second mass flow on the discharge pipe and detect piece and vacuum pump.

As a preferred scheme of the vacuum furnace carbon potential dynamic detection device, the standard gas is a first mixed gas formed by mixing hydrogen and nitrogen, or the standard gas is a second mixed gas formed by mixing hydrogen and inert gas.

As a preferred scheme of the vacuum furnace carbon potential dynamic detection device, the carbon permeation tube is a thin film tube capable of permeating carbon, and the wall thickness of the thin film tube is between 0.01mm and 0.05 mm.

As a preferred scheme of the vacuum furnace carbon potential dynamic detection device, the vacuum furnace carbon potential dynamic detection device further comprises a bypass pipe, wherein one end of the bypass pipe is communicated with the inlet pipe, and the other end of the bypass pipe is communicated with the hearth.

As a preferred scheme of a vacuum furnace carbon potential dynamic detection device, be equipped with first valve and second valve on the admission pipe, first valve is located the import of admission pipe, the second valve is located along the mark gas flow direction bypass pipe's the upper reaches, and be located along the mark gas flow direction first mass flow detection spare with the low reaches of heating member.

As a preferable scheme of the vacuum furnace carbon potential dynamic detection device, a third valve is arranged on the bypass pipe, and the third valve is arranged at one end, close to the inlet pipe, of the bypass pipe.

As a preferred scheme of the dynamic carbon potential detection device for the vacuum furnace, a vacuum pressure gauge is arranged on the discharge pipe and is positioned outside the vacuum furnace.

As a preferred scheme of the dynamic detection device for the carbon potential of the vacuum furnace, a fourth valve and a fifth valve are arranged on the discharge pipe, the fourth valve is positioned at the downstream of the vacuum pressure gauge along the flow direction of the standard gas and is positioned at the upstream of the second mass flow detection part and the vacuum pump, and the fifth valve is arranged at an outlet of the discharge pipe.

As a preferred scheme of the vacuum furnace carbon potential dynamic detection device, a transition pipe is arranged between the inlet pipe and the carbon permeation pipe, one end of the transition pipe is communicated with the inlet pipe, the other end of the transition pipe is communicated with the carbon permeation pipe, and at least part of the transition pipe is positioned in the hearth.

As a preferred scheme of the vacuum furnace carbon potential dynamic detection device, the inlet pipe, the outlet pipe and the transition pipe are respectively communicating pipes which cannot permeate carbon.

The utility model has the advantages that: the utility model discloses a vacuum furnace carbon potential dynamic detection device is through placing the carbon permeability tube in the furnace of vacuum furnace to detect the piece real-time detection through first mass flow and second mass flow and pass through the carbon content in furnace infiltration carbon permeability tube, thereby calculate the carbon potential in the vacuum furnace, be convenient for the carbon potential in the furnace of real-time detection vacuum furnace, and adjust furnace's carbon potential according to actual need, the qualification rate of part has been improved, the probability that the carbon black appears in the part rear surface of being heated has been reduced.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings required to be used in the description of the embodiments of the present invention will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the contents of the embodiments of the present invention and the drawings without creative efforts.

Fig. 1 is a schematic view of a dynamic carbon potential detection device of a vacuum furnace according to an embodiment of the present invention.

In the figure:

11. an inlet pipe; 12. a carbon permeate tube; 13. a discharge pipe; 14. a bypass pipe; 15. a transition duct;

21. a first mass flow detector; 22. a heating member;

31. a second mass flow rate detecting member; 32. a vacuum pump; 33. a vacuum manometer;

41. a first valve; 42. a second valve; 43. a third valve; 44. a fourth valve; 45. a fifth valve;

100. a vacuum furnace wall; 200. and (4) a hearth.

Detailed Description

In order to make the technical problems, technical solutions and technical effects achieved by the present invention more clear, the embodiments of the present invention will be described in further detail with reference to the accompanying drawings, and obviously, the described embodiments are only some embodiments, not all embodiments of the present invention. Based on the embodiments in the present invention, all other embodiments obtained by those skilled in the art without creative efforts belong to the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. Wherein the terms "first position" and "second position" are two different positions.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection or a removable connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

As shown in fig. 1, the present embodiment provides a dynamic carbon potential detection device for a vacuum furnace, which includes an inlet tube 11, a carbon permeation tube 12 and an outlet tube 13 that are sequentially connected, the carbon permeation tube 12 is located in a furnace 200 of the vacuum furnace, the inlet tube 11 is provided with a first mass flow rate detection component 21 and a heating component 22 for heating a standard gas in the inlet tube 11, and the outlet tube 13 is provided with a second mass flow rate detection component 31 and a vacuum pump 32.

Specifically, the first mass flow rate detecting element 21 and the second mass flow rate detecting element 31 of the present embodiment are mass flow rate meters, which can accurately detect the mass flow rate passing through per unit time, and the heating element 22 is an electric heater. In other embodiments, the first mass flow detecting element 21 and the second mass flow detecting element 31 may also be other detecting elements capable of detecting mass flow, and the heating element 22 may also be other structural elements capable of heating the standard gas, which is specifically selected according to actual needs.

The vacuum furnace carbon potential dynamic detection device that this embodiment provided is through placing carbon permeation tube 12 in the furnace 200 of vacuum furnace, and detect the carbon content in furnace 200 infiltration carbon permeation tube 12 through first mass flow detection piece 21 and second mass flow detection piece 31 real-time, thereby calculate the carbon potential in the vacuum furnace, be convenient for the carbon potential in the furnace 200 of real-time detection vacuum furnace, and adjust furnace 200's carbon potential according to actual need, the qualification rate of part has been improved, the probability of carbon black appears in the part rear surface of being heated has been reduced.

The standard gas in this embodiment is a first mixed gas of hydrogen and nitrogen, and since hydrogen is flammable, the percentage of hydrogen and nitrogen is required to be within a safe ratio range in order to increase the safety of the standard gas. On the premise of ensuring the safety of the standard gas, the mixing ratio of the hydrogen and the nitrogen is related to the surface area of the carbon permeation tube 12, and the larger the surface area of the carbon permeation tube 12 is, the larger the percentage of the hydrogen in the first mixed gas is. In addition, on the premise of ensuring the safety of the standard gas, the mixing proportion of the hydrogen and the nitrogen is also related to the carbon potential in the hearth 200, the larger the carbon potential in the hearth 200 is, the larger the percentage of the hydrogen in the first mixed gas is, so as to ensure that the carbon permeating from the hearth 200 to the inner wall of the carbon permeation tube 12 through the closing of the carbon permeation tube 12 can completely react with the hydrogen, and avoid the phenomenon that the carbon is too much to cause the detected carbon potential to be smaller than the actual value.

Of course, in other embodiments of the present invention, the standard gas is a second mixed gas of hydrogen and inert gas, wherein the percentage of hydrogen in the first mixed gas is positively correlated with the surface area of the carbon permeation tube 12 and the carbon potential in the furnace 200, or in other embodiments, the standard gas is a third mixed gas of hydrogen and a third gas, wherein the third mixed gas neither participates in the reaction nor affects the reaction, and the third gas is selected according to actual needs.

The carbon permeation tube 12 of the present example is a carbon permeable thin film tube made of iron, and the thin film tube has a wall thickness of 0.03 mm. In particular, to ensure good permeability of the thin film tube, in other embodiments, the thin film tube typically has a wall thickness of between 0.01mm and 0.05 mm. Since the wall thickness of the carbon penetration pipe 12 is very thin, carbon can penetrate in a very short time, and the gas in the standard gas has a strong decarbonization effect, so that the carbon in the carbon penetration pipe 12 is separated out and reacts with the standard gas to take away the carbon in the carbon penetration pipe 12. Of course, in other embodiments of the present invention, the material of the carbon permeable tube 12 is not limited to iron in this embodiment, and may also be other high temperature resistant materials, and the wall thickness of the carbon permeable tube 12 may be determined according to the adsorption characteristic and diffusion characteristic of the material to carbon, the high temperature strength of the material and the manufacturing process, and is not limited to 0.01mm to 0.05mm in this embodiment.

As shown in fig. 1, the vacuum furnace carbon potential dynamic detection device of the present embodiment further includes a bypass pipe 14 and a transition pipe 15, wherein one end of the bypass pipe 14 is communicated with the carbon permeation pipe 12, and the other end is communicated with the furnace 200. Specifically, one end of the bypass pipe 14 passes through the vacuum furnace wall 100 and is communicated with the inlet pipe 11, the transition pipe 15 is arranged between the inlet pipe 11 and the carbon permeation pipe 12, one end of the transition pipe 15 is communicated with the inlet pipe 11, the other end of the transition pipe is communicated with the carbon permeation pipe 12, and at least part of the transition pipe 15 is positioned in the furnace chamber 200. When the vacuum furnace is started to vacuumize the hearth 200 of the vacuum furnace, the bypass pipe 14 is communicated with the carbon permeation pipe 12, so that the consistency of the vacuum degree in the carbon permeation pipe 12 and the vacuum degree in the hearth 200 can be ensured, the phenomenon that the carbon permeation pipe 12 is deformed or broken due to the fact that the vacuum degree in the hearth 200 is large and the vacuum degree of the carbon permeation pipe 12 is small is avoided, and the service life of the carbon permeation pipe 12 is prolonged.

Of course, in other embodiments of the present invention, the bypass pipe 14 may not be provided, but the vacuum pump 32 directly vacuumizes the carbon permeation pipe 12 to make the vacuum degree in the carbon permeation pipe 12 the same as the vacuum degree of the furnace 200, so as to avoid the deformation or fracture of the carbon permeation pipe 12 and ensure the safety of the carbon permeation pipe 12.

In order to ensure the accuracy of the measurement, the inlet pipe 11, the outlet pipe 13, and the transition pipe 15 are required to be communicating pipes that are impermeable to carbon.

The inlet pipe 11 of this embodiment is provided with a first valve 41 and a second valve 42, the first valve 41 and the second valve 42 are located outside the furnace 200, the first valve 41 is located at the inlet of the inlet pipe 11, and the second valve 42 is located upstream of the bypass pipe 14 in the flow direction of the standard gas and downstream of the first mass flow detecting element 21 and the heating element 22 in the flow direction of the standard gas. The third valve 43 is disposed on the bypass pipe 14, and the third valve 43 is disposed at one end of the bypass pipe 14 close to the inlet pipe 11 and outside the furnace 200.

The exhaust pipe 13 of this embodiment is provided with a vacuum gauge 33, and the vacuum gauge 33 is located outside the vacuum furnace to detect the degree of vacuum in the carbon permeation tube 12 so that the degree of vacuum in the carbon permeation tube 12 is the same as the degree of vacuum in the furnace chamber 200. The discharge pipe 13 is provided with a fourth valve 44 and a fifth valve 45, the fourth valve 44 and the fifth valve 45 are positioned outside the furnace 200, the fourth valve 44 is positioned downstream of the vacuum pressure gauge 33 along the flow direction of the standard gas and upstream of the second mass flow rate detecting element 31 and the vacuum pump 32, and the fifth valve 45 is arranged at the outlet of the discharge pipe 13.

It should be noted that the first valve 41, the second valve 42, the third valve 43, the fourth valve 44, and the fifth valve 45 in this embodiment may be manually opened or closed valves, or valves such as automatically opened or closed electromagnetic valves, which are specifically set according to actual needs.

Specifically, when the vacuum furnace is vacuumized, the first valve 41, the second valve 42, the fourth valve 44 and the fifth valve 45 are all in a closed state, the third valve 43 is in an open state, and the gas in the carbon permeation tube 12 can enter the furnace chamber 200 through the bypass tube 14, so that the difference between the vacuum degree in the carbon permeation tube 12 and the vacuum degree in the furnace chamber 200 is not large, and at the moment, the vacuum pressure gauge 33 can detect the vacuum degree in the carbon permeation tube 12 in real time. When the standard gas is required to be introduced and the carburizing atmosphere is introduced into the furnace 200, the third valve 43 is closed and the first valve 41, the second valve 42, the fourth valve 44 and the fifth valve 45 are simultaneously opened, the standard gas is primarily heated by the heating element 22 and then is reheated in the transition pipe 15 of the furnace 200, so that the hydrogen of the standard gas reaches the minimum temperature required for reaction with carbon, thereby ensuring that the carbon concentration of furnace gas outside the carbon permeation pipe 12 and the carbon concentration inside the carbon permeation pipe 12 reach dynamic balance, the carburizing atmosphere decomposes carbon in the furnace 200, the carbon is adsorbed by the standard gas through the carbon permeation pipe 12 and reacts with the hydrogen, and finally the gas is extracted through the vacuum pump 32 on the exhaust pipe 13. At the outlet of the discharge pipe 13, other devices such as a collection tank may be connected for adsorbing or collecting the gas discharged from the discharge pipe 13.

Specifically, the content of carbon in the furnace 200 entering the carbon permeation tube 12 through the tube wall of the carbon permeation tube 12 is calculated according to the difference between the first mass flow value detected by the first mass flow detection element 21 and the second mass flow value detected by the second mass flow detection element 31, and the steel carbon potential of the carbon permeation tube is obtained according to the adsorption surface area of the carbon permeation tube 12 and the iron content of the carbon permeation tube 12, where the steel carbon potential is the initial carbon potential CP1 of furnace gas in the furnace 200, and the actual carbon potential CP of the furnace gas in the furnace 200 is K1 × K2 × CP1, where K1 is related to the material of the carbon permeation tube 12, K1 in this embodiment is 1, and K2 is an overall correction coefficient.

Specifically, the ratio of the experimental carbon potential of the furnace gas obtained by the same carbon permeation tube 12 in the same furnace gas environment and using the same carbon permeation tube obtained by the experiment to the product of the actual initial carbon potentials CP1 and K1 is the overall correction coefficient K2. After the actual carbon potential CP is obtained, the actual carbon potential is compared with the preset carbon potential set in the processing process, and the content of the carburizing atmosphere added into the hearth 200 is adjusted, so that the actual carbon potential in the hearth 200 is ensured to be consistent with the preset carbon potential, and the qualification rate of parts is improved.

Further, the dynamic carbon potential detection device of the vacuum furnace of the embodiment further includes a controller, the controller is respectively connected with the first mass flow detection element 21, the heating element 22, the second mass flow detection element 31, the vacuum pump 32 and the vacuum pressure gauge 33, the controller may be a centralized or distributed controller, for example, the controller may be an individual single chip microcomputer or may be formed by a plurality of distributed single chip microcomputers, and a control program may be run in the single chip microcomputers, so as to receive signals of the first mass flow detection element 21, the second mass flow detection element 31 and the vacuum pressure gauge 33 and control the heating element 22 and the vacuum pump 32 to realize functions thereof.

When the vacuum furnace carbon potential dynamic detection device is adopted to detect the actual carbon potential in the furnace, the specific operation steps are as follows:

step one, starting a vacuum pump 32 and a heating element 22, introducing standard gas into an inlet pipe 11, and enabling the standard gas to flow through the inlet pipe 11, a carbon permeation pipe 12 and an exhaust pipe 13 in sequence;

step two, the mass flow of the gas in the inlet pipe 11 detected by the first mass flow detector 21 is a first mass flow value, and the mass flow of the gas in the outlet pipe 13 detected by the second mass flow detector 31 is a second mass flow value;

step three, when the first mass flow value is the same as the second mass flow value, introducing carburizing atmosphere into the hearth 200 of the vacuum furnace;

step four, decomposing carbon in the carburizing atmosphere, and calculating the actual carbon potential in the furnace according to the first mass flow value and the second mass flow value in the process that the carbon permeates into the inner wall of the carbon permeation tube 12 and reacts with the standard gas;

and step five, adjusting the flow of the carburizing atmosphere entering the hearth according to the difference value of the actual carbon potential and the preset carbon potential at the corresponding processing stage, so that the actual carbon potential is the same as the preset carbon potential.

Before the first step, when the vacuum furnace is started and vacuumized, the first valve 41, the second valve 42, the fourth valve 44 and the fifth valve 45 need to be closed at the same time, the first valve 41 is opened to prevent the carbon permeation tube 12 from deforming or cracking, and the third valve 43 is closed when the temperature in the vacuum furnace reaches the preset temperature and the vacuum degree reaches the preset vacuum degree.

In the process of the first step, the first valve 41, the second valve 42, the fourth valve 44 and the fifth valve 45 are simultaneously opened, the standard gas is introduced through the inlet pipe 11 to purge the inlet pipe 11, the transition pipe 15, the carbon permeation pipe 12 and the discharge pipe 13, and the residual gas in the discharge pipe 13 is purged to purge the carbon in the inlet pipe 11, the carbon permeation pipe 12, the discharge pipe 13 and the transition pipe 15 during the previous test. In the third step, when the first mass flow value and the second mass flow value are the same, it is determined that the carbon in the inlet pipe 11, the transition pipe 15, the carbon permeation pipe 12 and the exhaust pipe 13 is purged.

And in the process of the fifth step, when the actual carbon potential is less than the preset carbon potential, increasing the flow of the carburizing atmosphere to improve the actual carbon potential to enable the actual carbon potential to be consistent with the preset carbon potential, and when the actual carbon potential is greater than the preset carbon potential, reducing the flow of the carburizing atmosphere to enable the actual carbon potential to be consistent with the preset carbon potential.

The dynamic carbon potential detection device for the vacuum furnace provided by the embodiment can adjust the flow and the time of the carburizing atmosphere added into the hearth 200 in unit time according to actual needs, so that the carbon potential in the hearth 200 is changed, and the controllable and stable effect of the carbon potential in the vacuum furnace in the heat treatment process is further achieved.

It should be noted that the foregoing is only a preferred embodiment of the present invention and the technical principles applied. It will be understood by those skilled in the art that the present invention is not limited to the particular embodiments described herein, but is capable of various obvious changes, rearrangements and substitutions as will now become apparent to those skilled in the art without departing from the scope of the invention. Therefore, although the present invention has been described in greater detail with reference to the above embodiments, the present invention is not limited to the above embodiments, and may include other equivalent embodiments without departing from the scope of the present invention.

Claims (9)

1. The utility model provides a vacuum furnace carbon potential dynamic detection device, its characterized in that, is including admission pipe (11), carbon permeate tube (12) and discharge pipe (13) that communicate in proper order, carbon permeate tube (12) are located vacuum furnace's furnace (200), be equipped with first mass flow on admission pipe (11) and detect piece (21) and be used for the heating member (22) of mark gas in admission pipe (11), be equipped with second mass flow on discharge pipe (13) and detect piece (31) and vacuum pump (32).

2. The carbon potential dynamic detection device of the vacuum furnace according to claim 1, wherein the carbon permeation tube (12) is a thin film tube which can permeate carbon, and the wall thickness of the thin film tube is between 0.01mm and 0.05 mm.

3. The carbon potential dynamic detection device of the vacuum furnace according to claim 1, characterized by further comprising a bypass pipe (14), wherein one end of the bypass pipe (14) is communicated with the inlet pipe (11), and the other end is communicated with the furnace chamber (200).

4. The carbon potential dynamic detection device of the vacuum furnace according to claim 3, characterized in that a first valve (41) and a second valve (42) are arranged on the inlet pipe (11), the first valve (41) is arranged at the inlet of the inlet pipe (11), and the second valve (42) is arranged at the upstream of the bypass pipe (14) along the flow direction of the standard gas and at the downstream of the first mass flow detection element (21) and the heating element (22) along the flow direction of the standard gas.

5. The vacuum furnace carbon potential dynamic detection device according to claim 3, characterized in that a third valve (43) is arranged on the bypass pipe (14), and the third valve (43) is arranged at one end of the bypass pipe (14) close to the inlet pipe (11).

6. The carbon potential dynamic detection device of the vacuum furnace according to claim 1, wherein a vacuum pressure gauge (33) is arranged on the discharge pipe (13), and the vacuum pressure gauge (33) is positioned outside the vacuum furnace.

7. The dynamic carbon potential detection device for the vacuum furnace according to claim 6, wherein a fourth valve (44) and a fifth valve (45) are arranged on the discharge pipe (13), the fourth valve (44) is positioned downstream of the vacuum pressure gauge (33) along the flow direction of the standard gas and upstream of the second mass flow detection element (31) and the vacuum pump (32), and the fifth valve (45) is arranged at the outlet of the discharge pipe (13).

8. The vacuum furnace carbon potential dynamic detection device according to claim 1, characterized in that a transition pipe (15) is arranged between the inlet pipe (11) and the carbon permeation pipe (12), one end of the transition pipe (15) is communicated with the inlet pipe (11), the other end is communicated with the carbon permeation pipe (12), and at least part of the transition pipe (15) is positioned in the hearth (200).

9. The device for dynamically detecting the carbon potential of the vacuum furnace according to claim 8, wherein the inlet pipe (11), the outlet pipe (13) and the transition pipe (15) are respectively communicating pipes which are not permeable to carbon.

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