The present invention relates to a method for gas carburizing steel parts used, for example, in the automobile industry or machine industry.
When gas carburizing of steel treatment objects is carried out, the carburizing treatment time can be shortened by raising the carburizing temperature. However, if the carburizing temperature becomes too high, the treatment object melts down. For this reason, the carburizing temperature that has been conventionally used in practice was less than the eutectic point temperature (in the case of an iron-carbon equilibrium diagram shown in
In order to shorten the carburizing treatment time at the conventional carburizing temperature, the carburizing treatment was carried out till the concentration of carbon in the surface layer of the treatment object became higher than the final target value, and then diffusion treatment which caused the carbon in the surface layer of the treatment object to diffuse was carried out in a high-temperature atmosphere with a carbon concentration less than that of the carburizing atmosphere, thereby decreasing the carbon concentration in the surface layer to the final target value (Japanese Examined Patent Publication No. 1994-45868).
However, when the carburizing temperature is limited to a temperature less than the eutectic point temperature, the diffusion rate of carbon atoms in the treatment object is restricted. Therefore, the carburizing time cannot be shortened significantly. Thus, the problem is that the diffusion treatment requires a long time, thereby reducing productivity.
It is an object of the present invention to provide a method of gas carburizing capable of resolving the aforesaid conventional problems.
A method of gas carburizing according to an aspect of the present invention comprises the steps of predetermining limiting carburizing conditions at which the surface layer of a sample of a steel treatment object present in a carburizing atmosphere is austenitized without melting at a carburizing temperature which is not higher than a peritectic point temperature at which δ iron and liquid phase are transformed into γ iron and not less than a eutectic point temperature at which liquid phase is transformed into γ iron and cementite; and gas carburizing the treatment object under carburizing conditions which are set so as not to contradict the limiting carburizing conditions, at a carburizing temperature which is not higher than the peritectic point temperature and not less than the eutectic point temperature, wherein the limiting carburizing conditions comprise an upper limit value of a partial pressure of carburizing gas in the carburizing atmosphere at which the surface layer of the sample is austenitized without melting. Thus, the carburizing time is shortened by gas carburizing the treatment object which is austenitized by being heated to a highest possible temperature. By increasing the carburizing gas concentration in the carburizing atmosphere, the hardened layer of the treatment object can be prevented from becoming shallow and have sufficient thickness within a short time.
The treatment object is austenitized when heated to a temperature above the GS line or ES line in the iron-carbon equilibrium diagram shown in
It is preferred that the limiting carburizing conditions comprise an upper limit value of carburizing temperature and an upper limit value of carburizing time at which the surface layer of the sample is austenitized without melting, the relationship between the upper limit value of the partial pressure of carburizing gas, the upper limit value of carburizing temperature, and the upper limit value of carburizing time is predetermined, and the partial pressure of carburizing gas, carburizing temperature, and carburizing time are set such that the carburizing conditions of the treatment object do not contradict the limiting carburizing conditions which satisfy the predetermined relationship. The upper limit value of the partial pressure of carburizing gas, the upper limit value of carburizing temperature, and the upper limit value of carburizing time serving as the limiting carburizing conditions are interrelated and one of the upper limit values can be found by fixing the other two conditions among the partial pressure of carburizing gas, carburizing temperature, and carburizing time. As a result, the conditions providing for the fastest possible carburization can be easily set within a range in which the surface layer of the treatment object is not melted.
A method of gas carburizing according to another aspect of the present invention is characterized in that when gas carburization of a steel treatment object is carried out, a carburizing temperature is set at a temperature which is not higher than a peritectic point temperature (it is the J point temperature which is 1494° C. in the case shown in
As a result, the carburizing time can be shortened significantly by raising the carburizing temperature. Moreover, because the concentration of carbon in the surface layer of the treatment object does not exceed the set target value, the carbon diffusion treatment process is unnecessary. As a result, productivity can be increased. Furthermore, the gas carburizing treatment process can be carried out in series with other heat treatment processes. Therefore, it is preferred that the treatment object is cooled without carrying out a diffusion treatment after the gas carburization has been carried out. It is also preferred that the treatment object is reheated after the cooling. The reheating is carried out, for example, by induction heating. It is also preferred that quenching treatment of the reheated treatment object is carried out. Cooling for the quenching treatment is carried out, for example, by oil cooling or gas cooling. In terms of shortening the carburizing time, it is preferred that the carburizing temperature is set at 1200° C. or higher. In this case, prior to implementing the method of gas carburizing, it is preferred that limiting carburizing conditions are predetermined, those conditions are set such that the surface layer of a sample of a steel treatment object present in a carburizing atmosphere is austenitized without melting at a carburizing temperature which is not higher than the peritectic point temperature at which δ iron and liquid phase are transformed into γ iron and is not less than the eutectic point temperature at which liquid phase is transformed into γ iron and cementite. The limiting carburizing conditions comprise the upper limit value of the partial pressure of carburizing gas in the carburizing atmosphere at which the surface layer of the sample is austenitized without melting. The treatment object is austenitized when heated to a temperature above the GS line or ES line in the iron-carbon equilibrium diagram shown in
In the present invention, the total pressure of carburizing atmosphere can be a normal pressure, or can be decreased or increased with respect to the normal pressure. The entire carburizing atmosphere can be a carburizing gas, or a gas mixture of a carburizing gas and a dilute gas can be used as the carburizing atmosphere. When a dilute gas is used, dilution is preferably carried out with an inert gas such as nitrogen gas or argon gas. No specific limitation is placed on the type of steel of the treatment object which is subjected to gas carburizing by the method according to the present invention, and the method of the present invention is applicable to any steel provided that it can be austenitized at a temperature which is not higher than the peritectic point temperature and not less than the eutectic point temperature. This steel can be not only a carbon steel but also an alloy steel.
In the present invention, it is preferred that heating of the treatment object and a sample thereof is carried out with means capable of high-speed heating of the surface layer thereof. The heating is preferably carried out, for example, by induction heating or laser heating. As a result, heating efficiency of the carburization object can be increased. Furthermore, because the carburizing treatment is simplified, quality control is facilitated. Thus, because the number of factors affecting the quality is small, even if quality problems such as spots, strains, or cracks in the treatment object are encountered, the causes thereof can be easily clarified. Furthermore, a wall covering the carburizing treatment space can be a cold wall and a waste gas combustion apparatus is unnecessary; therefore, degradation of working conditions is prevented and initial investment is reduced, moreover the method is applicable to single-item and small-scale production and can be easily incorporated into a production line, for example, in-line treatment of the individual production can be carried out. Because the conventional carburizing treatment furnace equipped with thermally insulating walls is not required, furnace heating or seasoning become unnecessary and running cost can be reduced.
In the present invention, the gas carburizing is preferably carried out, while causing a carburizing atmosphere comprising the carburizing gas at a constant partial pressure to flow. As a result, a constant partial pressure of carburizing gas can be maintained and treated products of uniform quality can be obtained.
The method of gas carburizing according to the present invention can greatly improve productivity.
The gas carburizing apparatus which is an embodiment of the present invention shown in
First, in order to carry out gas carburization of a sample 5′ of a steel treatment object, a thermocouple 6 is welded as a sensor for temperature detection to the surface layer of the sample 5′ set in the heating device 2. Then, the pressure inside the vacuum container 1 is reduced by evacuating the vacuum container 1 with the vacuum pump 3. At this time, the pressure inside the vacuum container 1 is preferably about 27 Pa or less. Means for detecting the temperature is not limited to a thermocouple.
After such pressure reduction, a gas for carburizing atmosphere is introduced from the gas source 4 into the vacuum container 1. As a result, the vacuum container 1 is filled with the carburizing atmosphere and the total pressure of the carburizing atmosphere is raised. For example, the pressure of the carburizing atmosphere inside the vacuum container 1 is raised to about 80 kPa. The carburizing atmosphere is composed of a carburizing gas and a dilute gas. No specific limitation is placed on the type of the carburizing gas or dilute gas. The carburizing gas of the present embodiment is methane gas and the dilute gas is nitrogen gas. Using a hydrocarbon gas as the carburizing gas makes it possible to realize a non-oxidizing carburization. The carburizing gas is not limited to hydrocarbon gases. The carburizing atmosphere may also be composed only of a carburizing gas.
In order to maintain a constant total pressure of carburizing atmosphere inside the vacuum container 1, the gas for carburizing atmosphere is supplied from the gas source 4 into the vacuum container 1 at a constant flow rate, and the gas for carburizing atmosphere is released by the vacuum pump 3 at a constant flow rate. As a result, the gas for carburizing atmosphere flows inside the vacuum container 1 at a constant flow rate of, for example, 0.5 L/min, and the total pressure of the carburizing atmosphere is maintained at, for example, about 80 kPa. Thus, the carburizing atmosphere containing a carburizing gas at a constant partial pressure flows inside the vacuum container 1. The partial pressure of carburizing gas is a value obtained by multiplying the total pressure of carburizing atmosphere inside the vacuum container 1 by a molar fraction or volume percent of the carburizing gas. Therefore, the set value of the partial pressure of carburizing gas can be adjusted by changing the total pressure of carburizing atmosphere inside the vacuum container 1 or by changing the flow rate ratio of the carburizing gas and dilute gas.
Then, the sample 5′ is heated with the heating device 2 to a set carburizing temperature. The carburizing temperature is not higher than the peritectic point temperature at which δ iron and liquid phase are transformed into γ iron and not less than the eutectic point temperature at which liquid phase is transformed into γ iron and cementite. The set value of the carburizing temperature can be adjusted by changing the output of the heating device 2 to the coil 2a.
When the sample 5′ is gas carburized by holding for the set carburizing time under the set partial pressure of carburizing gas and the set carburizing temperature, it is checked to see whether the surface layer of the sample 5′ is melted or not.
If the surface layer of the sample 5′ has not melted during the carburization, another carburization of another sample 5′ is carried out by increasing the set value of the partial pressure of carburizing gas. If the surface layer of the sample 5′ has melted, another carburization of another sample 5′ is carried out by decreasing the set value of the partial pressure of carburizing gas. By repeating this process, the upper limit value of the partial pressure of carburizing gas is predetermined as a limit carburizing condition at which austenitization is conducted without melting the surface layer of the sample 5′.
A method for predetermining the upper limit value of the partial pressure of carburizing gas by fixing the carburizing temperature and carburizing time was described hereinabove, but this method can be appropriately modified without departing from the essence of the present invention. Thus, the upper limit value of carburizing time can be found by fixing the partial pressure of carburizing gas and carburizing temperature, or the upper limit value of carburizing temperature can be found by fixing the partial pressure of carburizing gas and carburizing time.
Gas carburization of a steel treatment object 5 is thereafter carried out by using the above-described apparatus for gas carburization under the carburizing conditions which are set so as not to contradict the limiting carburizing conditions satisfying the predetermined relationship. Carburization of the steel treatment object 5 can be carried out in the same manner as carburization of the sample 5′.
To be more precise, as shown in
For example, when gas carburization of the steel treatment object 5 is carried out, the carburizing temperature is set at a temperature which is not higher than the peritectic point temperature at which δ iron and liquid phase are transformed into γ iron and not less than the eutectic point temperature at which liquid phase is transformed into γ iron and cementite. Furthermore, the target value of carbon concentration in the surface of the treatment object 5 is set at a value which is not higher than a value at which the surface of the treatment object 5 is not melted at the set carburizing temperature. Further, the partial pressure of carburizing gas in the carburizing atmosphere is set at a value at which the carbon concentration in the surface of the treatment object can reach the set target value as a result of gas carburization carried out during a preset period. The set value of the partial pressure of carburizing gas corresponding to the carburizing time can be predetermined by experiments. The set values of the carburizing time and partial pressure of carburizing gas are less than the aforesaid upper limit values corresponding to the set temperature. Therefore, the setting of the carburizing time and partial pressure of carburizing gas is facilitated by predetermining the aforesaid upper limit values.
For example, because the surface of the treatment object 5 starts melting at a carbon concentration of about 1.15 wt. % at a carburizing temperature of 1573 K, the relationship between the carburizing treatment time required for the surface of the treatment object 5 to start melting at a carburizing temperature of 1573 K, the partial pressure of carburizing gas, and the concentration of carbon in the surface is expressed by
Gas carburizing is carried out by holding the treatment object 5 for a set carburizing time under the aforesaid set partial pressure of carburizing gas and set carburizing temperature. Once the set carburizing time has elapsed, the carburizing is stopped by stopping the supply of carburizing gas or terminating the heating with the heating device 2.
With the method of gas carburizing according to the present invention, the carburizing time can be greatly shortened because the carburizing temperature range is set between not higher than the peritectic point temperature and not less than the eutectic temperature. Moreover, setting the partial pressure of carburizing gas to not higher than the predetermined upper limit value makes it possible to carry out the carburization at a high temperature without melting the surface layer of the steel treatment object 5. For example, the diffusion coefficient of carbon atoms in γ iron is 3.59×10−5 mm2/sec at a temperature of 1000° C., but increases to ten or more times, that is, 43×10−5 mm2/sec at a temperature of 1300° C. Thus, the migration speed of carbon atoms at a temperature of 1300° C. is not less than tenfold that at a temperature of 1000° C. Therefore, the time required to obtain the desired carburization depth can be greatly reduced and the usual carburization depth can be obtained at a carburizing time of about 1 to 10 min. Moreover, because the concentration of carbon in the surface layer of the treatment object 5 does not exceed the set target value, a carbon diffusion treatment step becomes unnecessary. As a result, the carburizing treatment time can be greatly shortened and the productivity can be increased. Furthermore, the gas carburization treatment step can be carried out in series with other heat treatment steps. Setting the carburizing temperature at not less than 1200° C. is preferred from the standpoint of shortening the carburizing time, and this temperature can be set at not less than 1300°.
Furthermore, because gas carburization is carried out while causing the carburizing atmosphere comprising the carburizing gas at a constant partial pressure to flow inside the vacuum container 1, a constant partial pressure of carburizing gas can be maintained and the uniformity of the quality of treatment object 5 can be improved. Moreover, no soot generation was observed in the carburizing treatment implemented according to the present invention, and in this respect, too, the present invention is greatly superior to the conventional vacuum carburizing.
Once the aforesaid gas carburizing has been completed, the treatment object 5 is cooled without carrying out the diffusion treatment. No specific limitation is placed on the cooling method, and natural cooling or a variety of forced cooling methods can be used. Furthermore, the treatment object 5 subjected to gas carburization is preferably quenched by reheating after cooling and then rapidly cooling. A secondary quenching may also be carried out by employing the primary cooling as a rapid cooling. The atmosphere for carrying out the quenching is preferably a neutral protective atmosphere, that is, the atmosphere in which the treatment object is neither carburized nor decarburized at this temperature, but the treatment can be carried out in another atmosphere of such as inert gas. The reheating temperature for quenching is set at not less than the temperature at which at least the surface layer of the treatment object 5 is austenitized above the GS line or ES line in the equilibrium diagram shown in
With the method of gas carburizing of the above-described embodiment according to the present invention, the limiting carburizing conditions were predetermined and gas carburization was carried out under the carburizing conditions that are set so as not to contradict the limiting carburizing conditions. The treatment object 5 had a shape of right cylinder with a diameter of 10 mm and a length of 52 mm made of a nickel-chromium-molybdenum steel (Japanese Industrial Standard SNCM420). In the present example, the carburized treatment object 5 was naturally cooled inside the vacuum container 1, hardened, polished, and finish processed with a diamond paste with a particle size of 3 micrometers, followed by hardness measurements and structure observations. The vacuum container 1 was purged prior to the carburization. The carburizing gas was methane and the dilute gas was nitrogen. During carburization, the gas for carburizing atmosphere was caused to flow inside the vacuum container 1 at a constant flow rate of 0.5 L/min. Hardening was carried out by holding the treatment object 5 for 10 min inside a quartz tube furnace kept at a temperature of 860° C. in which the nitrogen gas atmosphere was flowed and then quenched into oil. It goes without saying that furnaces of other types, including the induction heating furnaces, can be used for the hardening.
The metal structure prior to quenching of the surface layer of the treatment object 5 subjected to gas carburizing at a carburizing temperature of 1300° C. for a carburizing time of 1 min in accordance with the present invention is shown in
Gas carburization was carried out under the carburizing conditions that were set by the gas carburization method of the above-described embodiment of the present invention. The treatment object 5 had a shape of right cylinder with a diameter of 10 mm and a length of 52 mm made of a nickel-chromium-molybdenum steel (Japanese Industrial Standard SNCM420) as used in the above-described embodiment. The carburized treatment object 5 was naturally cooled inside the vacuum container 1, without being subjected to diffusion treatment, then was hardened, polished, and finish processed with a diamond paste with a particle size of 3 micrometers. The vacuum container 1 was purged prior to the carburization. The carburizing gas was methane and the dilute gas was nitrogen. Hardening was carried out by holding the treatment object 5 for 10 min inside a quartz tube furnace kept at a temperature of 860° C. in which nitrogen gas atmosphere was flowed and then quenched into oil. It goes without saying that furnaces of other types, including the induction heating furnaces, can be used for the hardening. The carburizing temperature was 1300° C., the carburizing time was 1 min, the concentration corresponding to the partial pressure of methane, which is the carburizing gas, in the carburizing atmosphere was 10 vol %, the target value of carbon concentration in the surface of the treatment object 5 was 0.74 wt. %, the total pressure of carburizing atmosphere was 80 kPa, and the gas for carburizing atmosphere was flowed inside the vacuum container 1 during the carburization at a constant flow rate of 0.5 L/min.
According to the above-described examples, the concentration of carbon in the surface of the treatment object 5 can be brought to the target value and a sufficient carburizing depth can be obtained without employing a diffusion treatment. By contrast,
The present invention makes it possible to shorten significantly the carburizing time by raising the carburizing temperature. Moreover, because the concentration of carbon in the surface layer of the treatment object 5 does not exceed the set target value, the carbon diffusion treatment becomes unnecessary and productivity can be increased.
The present invention is not limited to the above-described embodiments and examples and can be modified variously within the scope of the present invention.
Number | Date | Country | Kind |
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PCT/JP02/05767 | Jun 2002 | WO | international |
2002-342505 | Nov 2002 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP03/05422 | 4/28/2003 | WO | 00 | 2/19/2004 |
Publishing Document | Publishing Date | Country | Kind |
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WO03/104516 | 12/18/2003 | WO | A |
Number | Name | Date | Kind |
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2012165 | Hansen et al. | Aug 1935 | A |
6106636 | Naito et al. | Aug 2000 | A |
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2 284 616 | Jun 1995 | GB |
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10-121128 | May 1998 | JP |
11-200009 | Jul 1999 | JP |
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Number | Date | Country | |
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20050205164 A1 | Sep 2005 | US |