EP3156507B1 - Method and device for generation and treatment of protection and/or reaction gases especially for heat treatment of metals - Google Patents

Description

The invention relates to a method according to claim 1 for the production and / or treatment of protective and / or reaction gases for the heat treatment of metals, in particular for carburizing and / or for preventing the decarburization of metal components. The invention further relates to a device according to claim 10 for the generation and / or treatment of protective and / or reaction gases. - In the heat treatment of metals for carburizing the metals or metal components, a heat treatment plant or a heat treatment furnace is gassed with reducing protective and / or reactive gases. These protective and / or reaction gases usually consist essentially of carbon monoxide, hydrogen, nitrogen, water vapor and carbon dioxide. Gas components of these protective and / or reaction gases can be obtained in particular by thermal decomposition of hydrocarbon-containing substances, for example by thermal decomposition of methanol. The resulting gas components are also called fission gas (s) or fission gas mixture.

From practice different methods of the type mentioned are known. So it is already known to inject a mixture of nitrogen and methanol in a heat treatment plant, so that at the high heat treatment temperatures of, for example, 850 to 950 ° C in the heat treatment plant protection and / or reaction gases are formed with the above-mentioned gas components. After the protective and / or reaction gases have flowed through the heat treatment plant, they are discharged from the plant and burned or flared for safety reasons. This is associated with a significant effort and cost the protection and / or reaction gas production and supply. In addition, the procedure is of environmental concern.

Out DE 10 2008 029 001 B3 a method of the type mentioned is known. Here protective and / or reaction gases are used in a discontinuous batchwise operated chamber furnace system. Within this heat treatment plant, the protective and / or reaction gases are generated at the high heat treatment temperatures of natural gas and air. The protective and / or reaction gases are recirculated in the heat treatment plant via a high-temperature catalyst and treated with hydrocarbon gas. This procedure is - not least due to the use of high-temperature catalyst - associated with a disadvantageously high energy consumption. The recirculating protective and / or reaction gases also accumulate in this process with a disadvantageously high carbon dioxide and water vapor content. To compensate for this enrichment, additional feed gas must be added while increasing the input gas flow rate. This in turn means that excess protective and / or reaction gases must be burned or flared. This involves the disadvantages already described above.

DE4318400 discloses a heat treatment furnace (1) having a pressure change device (5) which can function at the gas inlet / gas outlet. The jet heat is used by the burning of the gaseous fuel to heat the gas mixture. The generator (7) of the cracked gases is located inside the furnace (1).

In contrast, the invention, the technical problem of providing a method of the type mentioned, in which the disadvantages described above can be avoided, which is simple and inexpensive to carry out and which is optimized in energy technology and environmental terms. The invention is further based on the technical problem of specifying a corresponding device for carrying out the method.

To solve the technical problem, the invention teaches a method according to claim 1 for the production and / or treatment of protective and / or reaction gases for heat treatment of metals, in particular for carburizing and / or preventing the decarburization of metal components, which by a - preferably continuously operated - heat treatment plant guided gases between at least one gas outlet of the system and at least one gas inlet of the system are circulated or recirculated and wherein the recirculating gases generated outside the heat treatment plant fission gas or fission gas mixture for renewal or replacement of gas components is mixed.

Hereinafter, instead of the term heat treatment plant and the term plant briefly used and instead of the term protective and / or reaction gases also briefly the term gases used. - According to the invention the protective and / or reaction gases are passed through the heat treatment plant and then discharged from the at least one gas outlet of the system and then returned to the gas inlet of the system and in turn introduced into the system, so that the circulation of the protective and / or reaction gases results. According to a preferred embodiment of the invention, the protective and / or reaction gases are first passed through the heat treatment plant and then discharged from the at least one gas outlet of the system and then returned within the furnace chamber of the heat treatment plant via a gas line from the furnace side separate line to the gas inlet of the system and again introduced into the plant. - Outside the plant to be renewed or replaced gas components of the protective and / or reaction gases in the form of a fission gas or fission gas mixture are metered. Conveniently, the content of gas components of the protective and / or reaction gases are measured or measured automatically and, depending on the determined need, fission gas or specifically fission gas is added.

The invention is based on the finding that due to the recycling of the protective and / or reaction gases according to the invention a method can be operated with little effort and low cost, in which the material use and energy use advantageously limits and targeted in the energy or heat can be used or recycled. In addition, the method according to the invention meets all environmental requirements. This will be explained in more detail below.

According to a particularly recommended embodiment of the invention, the heat treatment of the metals is carried out by a continuous procedure. It is thus in the heat treatment system used preferably a continuously operated heat treatment plant for the heat treatment of metals.

It is within the scope of the invention that at least one gas generating substance is introduced into the heat treatment plant when starting up the process or the method. Furthermore, it is within the scope of the invention that within the heat treatment plant - in situ - from this at least one gas generating substance protection and / or reaction gases are formed. In the recommended embodiment, the gas generant is methanol. Preferably, methanol is introduced as a gas generating substance together with at least one carrier gas, preferably with nitrogen as a carrier gas in the heat treatment plant. This introduction of the gas generating substance or the methanol - preferably in combination with nitrogen - is expediently only when starting the process and after the startup process, this fumigation is set again and according to the invention then the protective and / or reaction gases are circulated or recirculated. It is recommended that towards the end of the start-up process, said gassing is reduced to the extent that the recirculation of the protective and / or reaction gases can be started up. In the context of the process according to the invention, therefore, two feed processes for the gas components of the protective and / or reaction gases take place according to the preferred embodiment, namely the supply and decomposition of the at least one gas generating substance and the other during the cycle operation of the protective and / or reaction gases, the targeted or metered split gas supply. In particular, the cracked gas feed serves to maintain a sufficient carbon potential in the protective and / or reaction gases.

According to the invention, the generation of the fission gas or of the fission gas mixture takes place outside the plant or outside of the furnace with the supply of heat and the heat required for this purpose is taken from the exhaust gas from the heating of the heat treatment plant. In that regard, therefore, the waste heat of the heat treatment plant is utilized to generate the fission gas. It is within the scope of the invention that the generation of the cracked gas is carried out via an indirect heating by means of the waste heat from the heat treatment plant.

A particularly recommended embodiment of the method according to the invention is characterized in that the cleavage gas is generated by cleavage of at least one alcohol, preferably by cleavage of methanol. Preferably, the alcohol or preferably the methanol by means of a carrier gas, recommended added with nitrogen as the carrier gas. Particularly preferred in the context of the method according to the invention is the Recovery of the fission gas by catalytic low-temperature cracking. Conveniently, an alcohol - preferably methanol - subjected to such a catalytic low temperature cracking. Empfohlenermaßen the low temperature cleavage at a temperature of 200 to 400 ° C, preferably at a temperature of 240 to 370 ° C is performed. Particularly preferred is a temperature of 250 to 360 ° C for the low temperature cracking. The temperature of the catalytic low-temperature cracking is significantly lower than the temperature in the heat treatment plant (about 800 to 1000 ° C, in particular 850 to 950 ° C). It is within the scope of the invention that in the catalytic low-temperature cracking, the conditions of the cleavage are set precisely, so that as little carbon dioxide and as little water vapor as possible. Furthermore, it is within the scope of the invention that only the necessary supply of gas components for a replacement or renewal of the gas components of the protective and / or reaction gases is supplied by the catalytic low-temperature cracking. In that regard, the gas supply from the catalytic low-temperature cracking is expediently only a fraction of the volume flow of the recirculating protective and / or reaction gases.

A highly recommended embodiment of the method according to the invention is characterized in that the fission gas generated outside the heat treatment plant is passed through at least one cleaning device in order to at least reduce the content of at least one gas component. This at least one gas component is in particular carbon dioxide and / or water or water vapor. This avoids that a disadvantageous accumulation of the protective and / or reaction gases of carbon dioxide and / or water or water vapor takes place. According to a proven embodiment of the invention, the cracked gas is passed only partially and / or only when needed by the at least one cleaning device and to that extent an expedient embodiment variant is characterized in that the at least one cleaning device is accommodated in a bypass guide of the split gas. Preferably, an analysis or an automatic analysis of the cracking gas takes place on its carbon dioxide content and / or on its water content. Depending on the result of this analysis or measurement, the cracked gas is then passed, if necessary, partially or completely through the at least one cleaning device. Appropriately, care is taken that the carbon dioxide content and / or the water content in the protective and / or reaction gases does not exceed a certain desired value.

According to the recommended embodiment of the invention, at least one freezing device is present as a cleaning device, with this freezing device expediently carbon dioxide being frozen out of the cleavage gas. A particularly preferred embodiment of the invention in this context is characterized in that the cold generated during the nitrogen supply during the starting process is used for freezing in the freezing device. If nitrogen is used as the carrier gas during the starting process, expediently a relaxation of the frozen or frozen nitrogen takes place and the resulting cold is expediently used for freezing in the freezing device. According to the recommended variant of the invention can be used for the Ausfriereinrichtung also the cold, which arises during relaxation of the frozen nitrogen for the purpose of generating the carrier gas nitrogen for the supply of alcohol or methanol in the formation of the fission gas. According to an additional or alternative embodiment of the invention, at least one gas scrubber and / or at least one gas absorber is used as a cleaning device for scrubbing or removing a gas component, preferably for scrubbing out water vapor, from the cleavage gas. - One especially proven embodiment of the invention is characterized in that at least one Ausfriereinrichtung for freezing of carbon dioxide and at least one gas scrubber for washing water vapor are used as cleaning devices.

It is within the scope of the invention that the recirculating protective and / or reaction gases are heated prior to their introduction through the gas inlet into the heat treatment plant and indeed be heated by the hot exhaust gases from the heating of the system. To heat the protective and / or reaction gases prior to their reintroduction into the heat treatment plant so the waste heat from the heating of the heat treatment plant is utilized. Expediently, the heating of the protective and / or reaction gases takes place via at least one heat exchanger. Preferably, the protective and / or reaction gases are brought to a temperature during the heating, which is at least close to the heat treatment temperature in the heat treatment plant. According to a very preferred embodiment of the invention, the recirculating protective and / or reactive gases are passed through a high temperature line within the heat treatment plant during their recirculation over part of their way or over at least a large part of their way. They can not cool down and do not need to be heated additionally.

To solve the technical problem, the invention further teaches a device according to claim 10 for the production and treatment of protective and / or reaction gases for heat treatment of metals, in particular for carburizing and / or preventing the decarburization of metal components, wherein a heat treatment plant for heat treatment of the metals provided is, wherein the heat treatment plant at least one gas inlet and at least one gas outlet for recycling the protective and / or reaction gases and wherein outside of the heat treatment system, at least one split gas generating means for generating cracked gas or for generating a cracking gas mixture is arranged, wherein cracking gas is the protective and / or reaction gases can be mixed or metered. It is within the scope of the invention that the heat treatment plant is a continuous heat treatment plant.

Furthermore, it is within the scope of the invention that at least one starting device is provided for introducing at least one gas generating substance into the heat treatment system. Appropriately, this starting device is only when starting the process or the method in operation. Empfohlenermaßen is supplied to the starting device at least one hydrocarbon-containing gas generating substance, preferably at least one alcohol, preferably methanol as a gas generating substance. It has proved to be expedient that the at least one gas-generating substance - preferably methanol - together with at least one carrier gas - preferably together with nitrogen - is introduced into the heat treatment plant. It is within the scope of the invention that the operation of the starting device is set again after the starting process.

According to a preferred embodiment of the invention, the starting process is switched on when introducing heat treatment material into the system and when discharging heat treatment material from the system and preferably the recirculation of the protective and / or reaction gases is interrupted during this time. This switching on the starting process during the entry and / or removal of heat treatment material serves to maintain pressure during the Schleusungsvorganges in the system. To interrupt the recirculation of the reaction and / or protective gases during such Schleusungsvorganges the recirculation circuit, for example, short-circuited become. In addition, process-damaging contaminations of the re-cursing protective and / or reaction gases are reduced by lock flushing of the system.

Expediently, at least one pressure relief chamber is provided at the gas inlet and at the gas outlet of the heat treatment plant. According to one embodiment variant, each pressure relief chamber is assigned a gas delivery device. Incidentally, it is within the scope of the invention that at least one pressure sensor is arranged in each pressure relief chamber. In principle, temperature sensors can also be provided here.

It is within the scope of the invention that the recirculated protective and / or reaction gases are conducted via a recirculation line from the gas outlet of the heat treatment system to the gas inlet of the heat treatment system and in this way the circulation of the recirculating gas is realized. - Advantageously, the cracked gas from the split gas generating device is supplied via a supply line of the recirculation line and fed to a feed point in the recirculation line. According to a particularly preferred embodiment of the invention, at least one cleaning device for the cracking gas formed in the split gas generating device is arranged in a bypass line of the feed line. Conveniently, this bypass line begins in the flow direction behind the split gas generating device at a branch point in the supply line and preferably opens in front of the feed point for the recirculation line in the supply line. Empfohlenermaßen a volumetric flow controller is provided at the branch point of the supply line. In this way, the volumetric flow of the cracked gas passed via the bypass line and thus through the at least one cleaning device can be adjusted. ever if necessary, the cracked gas is passed partly or completely through the bypass line through the at least one cleaning device.

A recommended embodiment of the device according to the invention is characterized in that at least one cleaning device for removing at least one gas component from the cracking gas is present. The removal of the gas component or the gas components has already been explained in more detail above. It is preferably the removal of carbon dioxide and / or water or water vapor. At least one sensor for detecting the carbon dioxide content and / or water content of the split gas is preferably arranged in the flow direction behind the split gas generating device and expediently before the branch point of the feed line for the cracked gas. It is further recommended that at least one sensor for detecting the carbon dioxide content and / or water content in the recirculation line is arranged and preferably in the flow direction behind the feed point of the cracked gas. With the aid of this sensor or with the aid of these sensors, the extent or the volume flow of the cracked gas can be determined, which is to be guided through the bypass line and through the at least one cleaning device. Appropriately, this scheme is done automatically.

The invention is based on the finding that with the method according to the invention and with the device according to the invention, a relatively simple and inexpensive, in particular less expensive, heat treatment of the metals for carburizing the metals is possible. The protective gases and / or the reaction gases can be very completely recirculated or recycled and therefore can be largely dispensed within the scope of the invention on the combustion or flaring of excess protective and / or reaction gases. This is in comparison to the known methods in environmental terms of particular advantage. Incidentally, the resulting heat / energy or waste heat in the context of the method according to the invention can be exploited very largely and effectively, so that the invention is characterized by particular advantages in terms of energy technology. A device according to the invention for carrying out the method is constructed relatively compact and with little complexity. The realization of such a device is associated with relatively low costs.

The invention will be explained in more detail with reference to a drawing showing only one exemplary embodiment. The single FIGURE shows a very simplified block diagram relating to the method steps according to the invention.

In the figure, an apparatus for carrying out the method according to the invention for the production and / or treatment of protective and / or reaction gases for the heat treatment of metals and for the carburization of metal components is shown. The device according to the invention has a continuously operated heat treatment plant 1 with a gas inlet 3 and a gas outlet 2 for the circulating or for the recirculating protective and / or reaction gases. In this case, a pressure relief chamber 9, 10 is preferably arranged at the gas inlet 3 and at the gas outlet 2 and in the exemplary embodiment.

When the process is started, at least one gas-generating substance for producing gas components of the protective and / or reaction gases is introduced into the heat treatment plant 1 by means of the starting device 8, which is shown only schematically. Preferably and in the exemplary embodiment, methanol is introduced as a gas-generating substance and nitrogen as a carrier gas by means of the starting device 8 via the gas inlet 3 in the system 1. Appropriately, and in the embodiment are within the Annex 1 - as it were in situ - produces gas components for the protective and / or reaction gases from the methanol. The protective and / or reaction gases are then guided in the direction of the arrow from the gas inlet 3 through the system 1 to the gas outlet 2 and then in turn returned via the recirculation line 11 to the gas inlet 3 and recycled in this way. After starting the process, the starting device 8 is again put out of operation and the protective and / or reaction gases are recirculated without supplying further gas generating substances in the system.

For the replenishment or for the renewal of the gas components of the protective and / or reaction gases, a fission gas generating device 7 is provided in which fission gas or a fission gas mixture is generated which can be added to the recirculating in the recirculation line 11 protective and / or reaction gases. Preferably, the cracking gas is generated by catalytic cleavage of methanol. Empfohlenermaßen and in the embodiment, the fission gas generating means 7 is provided for a catalytic low temperature cracking of methanol at a temperature between 250 and 360 ° C. In this catalytic low-temperature cleavage of methanol, a cracked gas or fission gas mixture is formed, which consists essentially of carbon monoxide, hydrogen, carbon dioxide and water vapor. The cracked gas is introduced via a feed line 18 at a feed point 14 in the recirculation line 11. Empfohlenermaßen and in the exemplary embodiment, the cracking gas is passed as required via a bypass line 12 through cleaning devices 4, in which the carbon dioxide content and the water content of the cracking gas is reduced. For this purpose, a branch point 19 for the bypass line 12 is provided in the supply line 18. Here, the quantity or the volume flow of the cracked gas can be adjusted via the volumetric flow controller 15, which is to be guided via the bypass line 12 and the cleaning devices 4.

In the exemplary embodiment, a cleaning device 4 is designed as a freezing device 5 for carbon dioxide and a cleaning device 4 is designed as a gas scrubber 6 for the removal of water vapor. Preferably and in the embodiment, at least one sensor 13 for detecting the carbon dioxide content and / or water content of the quenching gas is arranged after the split gas generating device 7 and before the bypass line 12. Appropriately, and in the embodiment, such a sensor 13 is also provided behind the feed point 14 of the fission gas / fission gas mixture in the recirculation line 11. Depending on measured with these sensors 13 carbon dioxide and water contents can be adjusted or regulated with the arranged behind the split gas generating means 7 and at the branch point 19 volume flow regulator 15, the volume flow of the guided over the bypass line 12 fission gas.

Preferably and in the exemplary embodiment, the cracked gas emerging from the cleaning devices 4 is heated or reheated with the aid of a first heat exchanger 16. The heat for this first heat exchanger 16 is recommended and in the embodiment of the exhaust gas or waste heat from the heating of the heat treatment plant 1. Furthermore, a second heat exchanger 17 is provided in the recirculation line 11 for heating the recirculating protective and / or reaction gases. The heat of this second heat exchanger 17 is taken from the exhaust gas or the waste heat from the heating of the heat treatment plant 1. - A highly recommended embodiment of the invention is further characterized in that - as not shown in detail in the figure - the heat for the fission gas generating device 7 and for the catalytic low-temperature cracking of the methanol exhaust gas or waste heat of heating Heat treatment plant is removed. In this way, a particularly advantageous in terms of energy technology method can be performed.

It is still within the scope of the invention that are arranged at different points of the device according to the invention in the figure, not shown, pressure sensors for detecting the gas pressure. Thus, each pressure relief chamber 10, such a pressure sensor can be assigned as well as the recirculation line 11 in front of and behind the feed point 14 for the cracked gas. A pressure sensor can also be provided immediately after the fission gas generating device 7 or at the gas outlet of the fission gas generating device 7 and in the bypass line 12 with the cleaning devices 4. Furthermore, it is possible within the scope of the invention, feeding devices for an inert gas for the protection and / or reaction gases leading lines to provide inerting of these lines. Furthermore, temperature sensors can also be arranged at different locations of the device.

Claims (14)

1. A method for generating and/or treating inert gases and/or reaction gases for the heat treatment of metals, in particular for carburizing and/or preventing decarburizing of metal components, wherein the inert gases and/or reaction gases conducted through a heat treatment system (1) are conducted and/or recirculated between at least one gas outlet (2) of the system (1) and at least one gas inlet (3) of the system (1) in the circuit, wherein a cracked gas and/or a cracked gas mixture generated outside the system (1) is admixed with the recirculating gases for renewing and/or for replacing gas components of the inert gases and/or reaction gases, and wherein the recirculating inert gases and/or reaction gases are heated by means of the exhaust gases and/or the waste heat from the heating of the system (1) before the introduction thereof through the gas inlet (3) into the system (1).
2. The method according to Claim 1, wherein the heat treatment of the metals is carried out continually.
3. The method according to one of Claims 1 or 2, wherein at least one gas generating substance is introduced into the system (1) when the process is started, and wherein the inert gases and/or reaction gases are generated from the at least one gas generating substance.
4. The method according to one of Claims 1 to 3, wherein the cracked gas is generated by the supply of heat and wherein preferably the heat required therefor is removed from the exhaust gas from the heating of the heat treatment system (1).
5. The method according to one of Claims 1 to 4, wherein the cracked gas is generated by cracking at least one alcohol.
6. The method according to one of Claims 1 to 5, wherein the cracked gas and/or the cracked gas mixture is generated by catalytic low temperature cracking and wherein the catalytic low temperature cracking, in particular, is carried out at a temperature of 200 to 400°C.
7. The method according to one of Claims 1 to 6, wherein the cracked gas/cracked gas mixture is conducted through at least one cleaning apparatus (4) in order to reduce the content of at least one gas component of the cracked gas/cracked gas mixture, wherein the at least one gas component is preferably carbon dioxide and/or water.
8. The method according to Claim 7, wherein at least one freezing-out apparatus (5) is used as a cleaning apparatus (4) for freezing out carbon dioxide.
9. The method according to one of Claims 7 or 8, wherein at least one gas scrubber (6) is used as a cleaning apparatus (4) for removing water vapour.
10. A device for generating and/or treating inert gases and/or reaction gases for the heat treatment of metals, in particular for carburizing and/or preventing decarburizing of metal components - in particular for carrying out the method according to one of Claims 1 to 9 - wherein a heat treatment system (1) is provided for the heat treatment of the metals, wherein the heat treatment system (1) comprises at least one gas inlet (3) and at least one gas outlet (2) for circulating the inert gases and/or reaction gases, wherein at least one cracked gas generating apparatus (7) is arranged outside the heat treatment system (1) for generating cracked gas and/or a cracked gas mixture, which cracked gas and/or cracked gas mixture is able to be metered to the inert gases and/or reaction gases and wherein the recirculating inert gases and/or reaction gases are able to be heated by means of the exhaust gases and/or the waste heat from the heating of the system before the introduction thereof through the gas inlet (3) into the system (1).
11. The device according to Claim 10, wherein the heat treatment system (1) is a continuous heat treatment system (1).
12. The device according to one of Claims 10 or 11, wherein (in each case) at least one pressure relief chamber is arranged on the gas inlet (3) and/or on the gas outlet (2), and wherein preferably at least one pressure sensor is assigned to each gas inlet (3) and/or gas outlet (2).
13. The device according to one of Claims 10 to 12, wherein at least one starting device (8) is provided for introducing at least one gas generating substance into the heat treatment system (1).
14. The device according to one of Claims 10 to 13, wherein at least one cleaning apparatus (4) is present for removing at least one gas component from the cracked gas/cracked gas mixture.

Images