KR20220073084A - Control method of maximum power demand in multiple heat treatment furnaces - Google Patents

Abstract

The present invention relates to a method for controlling the maximum power demand of a multiple heat treatment furnace, wherein the maximum power demand used in a plurality of heat treatment furnaces during the heat treatment of products or parts is a heat treatment process: the first temperature raising step, the quenching step, the first cooling step, 1 Multiple heat treatment to cut off and control more power than necessary by adjusting, blocking, or partially cutting off power in a specific stage of one cycle consisting of the primary warming stage, the secondary temperature raising stage, the tempering stage, the secondary cooling stage, and the secondary thermal insulation stage. It relates to a method for controlling the maximum power demand of a furnace,
Specific means of the present invention are:
"In the first temperature raising step of charging a casting or mechanical parts into a plurality of heat treatment furnaces and raising the temperature from the initial room temperature to a temperature gradient of a certain temperature per hour to raise the temperature to a predetermined temperature range, and the first temperature raising step to a predetermined temperature A first cooling step of rapidly cooling the casting or mechanical parts in a heat treatment furnace after passing through the quenching step to maintain and the quenching step, and the first cooling step to keep the castings or mechanical parts at a constant temperature in the heat treatment furnace After passing through the first warming step and the first warming step, the second temperature raising step of raising the temperature of the casting or mechanical parts with a temperature gradient of a certain temperature per hour in the heat treatment furnace, and the second temperature raising step in the state where the temperature is raised to a certain temperature After undergoing the tempering step of maintaining and the tempering step, the secondary cooling step of rapidly cooling the casting or mechanical parts in the heat treatment furnace and the secondary cooling step, the casting or machine parts are kept at a constant temperature in the heat treatment furnace. Including the second warming step,
In the plurality of heat treatment furnaces, the power consumed in the first temperature raising step, the first cooling step, the first keeping warm step, the second temperature raising step, the second cooling step, and the second keeping warm step is collectively predetermined. A method for controlling the maximum power demand of a multiple heat treatment furnace, including controlling or blocking the

Description

Control method of maximum power demand in multiple heat treatment furnaces

The present invention relates to a method for controlling the maximum power demand of a multiple heat treatment furnace, wherein the maximum power demand used in a plurality of heat treatment furnaces during the heat treatment of products or parts is a heat treatment process in the first heating step, quenching step, first cooling step, 1 Multiple heat treatment that cuts off and controls more power than necessary by adjusting, blocking, or partially cutting off power in a specific stage of one cycle consisting of the primary warming stage, the secondary temperature raising stage, the tempering stage, the secondary cooling stage, and the secondary thermal insulation stage. It relates to a method for controlling the maximum demand power of a furnace.

Heat treatment is a thermal manipulation technique in which heating and cooling are performed to achieve the mechanical and physical properties required for metal materials (mainly steel materials). Thus, it can be represented as a technology to improve workability, and such heat treatment technology is also being developed gradually.

Such a conventional heat treatment method is a heating process in which a casting or mechanical part manufactured as a special cast iron is charged into a heat treatment furnace, and the temperature is continuously increased from an initial room temperature to a predetermined temperature gradient (change rate of temperature per hour) to the final temperature range. And, after going through the above heating process, a holding process of maintaining for a certain time in the heat treatment furnace for each thickness of the casting or mechanical parts under the final temperature range.

Then, after the above maintenance process, the casting or mechanical parts are taken out from the heat treatment furnace and air cooled from the final temperature to the initial room temperature, and after the cooling process, the castings or mechanical parts are put back into the heat treatment furnace. It is known that it is made through a tempering process of tempering at an appropriate temperature to impart toughness and uniform structure, and a cooling process in which the casting or mechanical parts are taken out of the heat treatment furnace after the tempering process and air-cooled to an initial room temperature. have.

However, since the conventional heat treatment method as described above continuously heats with a predetermined temperature gradient from the initial room temperature to the final temperature, the power consumed in the entire heat treatment process exceeds the reference power, so there is a risk of wasting power, and the temperature increase process and maintenance In the process, namely, quenching process, cooling process, tempering process and cooling process, it is possible to control and change the temperature except for the quenching process and the tempering process, where temperature change or control is impossible to prevent power wastage. Although it can be done, there is no specific technology development in the current state to prevent such power wastage.

Korean Patent Publication No. 10-1999-0068668 Korean Patent Publication No. 10-2004-0013801 Korean Patent Publication No. 10-2004-0013801 Republic of Korea Patent Registration No. 10-1147952

Accordingly, the present invention is to solve the above problems,

In the heat treatment of products or parts, the maximum demand power used in multiple heat treatment furnaces is converted into the heat treatment process: 1st temperature raising step, quenching step, 1st cooling step, 1st warming step, 2nd temperature raising step, tempering step, 2nd cooling step , Provides a method for controlling maximum demand for power in multiple heat treatment furnaces to minimize power wastage and loss by controlling or blocking power at a specific stage of one cycle consisting of the secondary warming step and cutting off and partially cutting off power more than necessary but there is a purpose

Specific means for achieving the above object are,

"In the first temperature raising step of charging a casting or mechanical parts into a plurality of heat treatment furnaces and raising the temperature from the initial room temperature to a temperature gradient of a certain temperature per hour to raise the temperature to a predetermined temperature range, and the first temperature raising step to a predetermined temperature A first cooling step of rapidly cooling the casting or mechanical parts in a heat treatment furnace after passing through the quenching step to maintain and the quenching step, and the first cooling step to keep the castings or mechanical parts at a constant temperature in the heat treatment furnace After passing through the first warming step and the first warming step, the second temperature raising step of raising the temperature of the casting or mechanical parts with a temperature gradient of a certain temperature per hour in the heat treatment furnace, and the second temperature raising step in the state where the temperature is raised to a certain temperature After undergoing the tempering step of maintaining and the tempering step, the secondary cooling step of rapidly cooling the casting or mechanical parts in the heat treatment furnace and the secondary cooling step, the casting or machine parts are kept at a constant temperature in the heat treatment furnace. Including the second warming step,

In the plurality of heat treatment furnaces, the power consumed in the first temperature raising step, the first cooling step, the first keeping warm step, the second temperature raising step, the second cooling step, and the second keeping warm step is collectively predetermined A method for controlling the maximum power demand of a multiple heat treatment furnace, including controlling or blocking the time period of

In the plurality of heat treatment furnaces, the power consumed in the first temperature raising step, the first cooling step, the first keeping warm step, the second temperature raising step, the second cooling step, and the second keeping warm step is partially predetermined. A method for controlling the maximum power demand of a multi-heat treatment furnace including adjusting or blocking over time;

The first heating step, the first cooling step, the first warming step, the second temperature raising step, the second cooling step, and the second warming step in any one or more heat treatment furnaces of the plurality of heat treatment furnaces A method for controlling maximum demand for power in a multi-heat treatment furnace comprising controlling or blocking power at a predetermined time in a batch;

The first heating step, the first cooling step, the first warming step, the second temperature raising step, the second cooling step, and the second warming step in any one or more heat treatment furnaces of the plurality of heat treatment furnaces A method for controlling maximum demand for power in a multi-heat treatment furnace, which includes controlling or cutting off electric power partially for a predetermined time;

After confirming the power state by sequencing the plurality of heat treatment furnaces, the first temperature raising step, the first cooling step, the first warming step, the second temperature raising step, the second cooling step, the second step of the heat treatment furnace sequentially A method for controlling the maximum power demand of a multi-heat treatment furnace, which includes controlling or blocking the electric power required in the car keeping warm step at a predetermined time,

After confirming the power state by sequencing the plurality of heat treatment furnaces, the first temperature raising step, the first cooling step, the first warming step, the second temperature raising step, the second cooling step, the second step of the heat treatment furnace sequentially The above object can be achieved by defining the "maximum demand power control method of a multiple heat treatment furnace, which includes partially adjusting or blocking the electric power required in the car warming step for a predetermined time" as its structural feature.

The present invention configured as described above uses the maximum demand power used in a plurality of heat treatment furnaces for heat treatment of products or parts, which is a heat treatment process: a first temperature raising step, a quenching step, a first cooling step, a first warming step, a second temperature raising step, It is possible to minimize power wastage and loss by cutting off and controlling more power than necessary by adjusting or blocking and partially blocking power in a specific step of one cycle consisting of a tempering step, a second cooling step, and a second warming step.

In the above, the present invention has been illustrated and described with specific preferred embodiments as examples, but the present invention is not limited to the above-described embodiments, and within the scope of not departing from the spirit of the present invention, it is common knowledge in the art to which the invention pertains. Various changes and modifications will be possible by those who have

1 is a flowchart of a method for controlling maximum demand power of a multi-heat treatment furnace according to the present invention;
2 is a block diagram in the method of controlling the maximum power demand of the multiple heat treatment furnace according to the present invention;
3 is a view showing the temperature change characteristics of each heat treatment furnace in the method of controlling the maximum power demand of the multiple heat treatment furnace according to the present invention;
4 is a diagram showing the power characteristics of the maximum demand power in the method for controlling the maximum demand power of the multiple heat treatment furnace according to the present invention.

Specific structural or functional descriptions of the embodiments according to the concept of the present invention disclosed in this specification are only exemplified for the purpose of explaining the embodiments according to the concept of the present invention, and the embodiments according to the concept of the present invention are Since various changes can be made and can have various forms, all changes, equivalents, or substitutes included in the spirit and scope of the present invention are included, and the terms or words used in the specification and claims are conventional or dictionary Not to be construed as limited to the meaning, of course, based on the fact that the inventor can appropriately define the concept of a term to describe his invention in the best way, meaning and concept consistent with the technical idea of the present invention should be interpreted as Accordingly, the embodiments described in the specification of the present invention and the configurations shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical spirit of the present invention. It should be understood that various possible equivalents and variations are possible or existent.

In addition, unless otherwise defined in the specification of the present invention, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. have Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present specification. does not

Hereinafter, the method of controlling the maximum power demand of the present invention, the present invention, of a multiple heat treatment furnace will be described in detail with the drawings.

1 is a flowchart of a method for controlling maximum power demand for a multiple heat treatment furnace according to the present invention, FIG. 2 is a block diagram for a method for controlling maximum power demand for a multiple heat treatment furnace according to the present invention, and FIG. 3 is a maximum power demand for a multiple heat treatment furnace according to the present invention. It is a view showing the temperature change characteristics of each heat treatment furnace in the control method, and FIG. 4 is a view showing the power characteristics of the maximum power demand in the method for controlling the maximum power demand of the multiple heat treatment furnace according to the present invention.

In general, the heat treatment process is

A first temperature raising step of charging a casting or mechanical parts into a plurality of heat treatment furnaces and raising the temperature from the initial room temperature to a temperature gradient of a certain temperature per hour to a predetermined temperature range;

A quenching step of maintaining the temperature in a state elevated to a predetermined temperature in the first temperature raising step;

A primary cooling step of rapidly cooling the casting or mechanical parts in a heat treatment furnace after the quenching step;

A first warming step of warming the casting or mechanical parts to a predetermined temperature in a heat treatment furnace after the first cooling step;

A second temperature raising step of raising the temperature of the casting or mechanical parts with a temperature gradient of a certain temperature per hour in a heat treatment furnace after passing through the first warming step;

A tempering step of maintaining the temperature in a state elevated to a predetermined temperature in the second temperature raising step;

A secondary cooling step of rapidly cooling the casting or mechanical parts in a heat treatment furnace after the tempering step;

After the secondary cooling step, it is a typical process to consist of a second warming step of keeping the casting or mechanical parts at a constant temperature in a heat treatment furnace.

Looking at most of the existing heat treatment related patents, there are many contents that have been applied for or registered by enabling specific temperature conditions to be characteristically implemented in each of the above steps.

The present invention does not entitle specific limitations in each step as described above, but in the heat treatment of the castings or mechanical parts charged to the heat treatment furnace, the heat treatment furnace is maintained in a vacuum state and then power is supplied to increase the temperature, quenching, By controlling the maximum demand power, which is the amount of power used in the process of quenching, warming, tempering, etc., the current power, target power, and maximum demand, which are predicted power, so as not to exceed the standard power supplied by electricity suppliers such as KEPCO, for example. As the power does not exceed the standard power, the power consumption is minimized and there is no problem in the heat treatment at the same time to minimize power wastage and loss,

In the quenching step (S2) and the tempering step (S6) of each step, the power cannot be cut off or adjusted because the constant temperature must be maintained for a certain period of time, and the remaining steps, that is, the first temperature raising step of all the heat treatment furnaces (S1) ), the first cooling step (S3), the first warming step (S4), the second heating step (S5), the second cooling step (S7), and the power consumed in the second warming step (S8) A multiple heat treatment furnace to optimize power consumption and minimize power waste and loss by controlling or blocking The method for controlling the maximum demand for electricity is presented.

Preferably, in all the heat treatment furnaces, that is, in the plurality of heat treatment furnaces, the first temperature raising step (S1), the first cooling step (S3), the first warming step (S4), the second temperature raising step (S5) , The secondary cooling step (S7), the second heating step (S8), including partially adjusting or blocking the power required for a predetermined time,

More preferably, the first temperature raising step (S1), the first cooling step (S3), the first keeping warm step (S4), the second temperature raising step (S1) in any one or more heat treatment furnaces of the plurality of heat treatment furnaces ( S5), the secondary cooling step (S7), including controlling or blocking the power required in the second warming step (S8) at a predetermined time in a batch,

In another method, the first temperature raising step (S1), the first cooling step (S3), the first warming step (S4), the second temperature raising step ( S5), the secondary cooling step (S7), the second heating step (S8), including partially adjusting or blocking the power required for a predetermined time,

In addition, after confirming the power state by sequencing all of the heat treatment furnaces, that is, the plurality of heat treatment furnaces, the first temperature raising step (S1), the first cooling step (S3), the first warming step (S4) of the heat treatment furnace sequentially ), the second temperature raising step (S5), the second cooling step (S7), and the second heating step (S8) including controlling or blocking the power required in the batch for a predetermined time,

Further, after confirming the power state by sequencing all the heat treatment furnaces, that is, the plurality of heat treatment furnaces, the first temperature raising step (S1), the first cooling step (S3), the first warming step of the heat treatment furnace sequentially ( S4), the second temperature raising step (S5), the second cooling step (S7), and the second heating step (S8) will include partially adjusting or blocking the power required in the predetermined time period.

By configuring as described above, the maximum demand power used in a plurality of heat treatment furnaces during heat treatment of products or parts is converted to the heat treatment process in the first temperature raising step, quenching step, first cooling step, first warming step, second temperature raising step, and tempering step. , the second cooling step, and the second warming step, by adjusting or blocking and partially cutting off the power in a specific step of the cycle, it is possible to cut off and control more power than necessary to minimize power wastage and loss.

As described above, although the present invention has been described with reference to the limited embodiments and drawings, the present invention is not limited to the above embodiments, of course, from the above description by those of ordinary skill in the art to which the present invention pertains. Of course, various modifications and variations may be possible.

Therefore, the technical spirit in the present invention should be understood by the claims described below, but it will be obvious that all equivalents or equivalent modifications thereof fall within the scope of the technical spirit of the present invention.

S1: 1st temperature raising step S2: quenching step
S3: 1st cooling stage S4: 1st warming stage
S5: Second temperature raising step S6: Tempering step
S7: Second cooling stage S8: Second warming stage

Claims (6)

The first temperature raising step of raising the temperature from the initial room temperature to a temperature gradient of a certain temperature per hour by charging the castings or machine parts into a plurality of heat treatment furnaces to raise the temperature to a predetermined temperature range, and maintaining the temperature in the state of being raised to a predetermined temperature in the first heating step After passing through the quenching step and the quenching step, the first cooling step of rapidly cooling the casting or machine part in a heat treatment furnace and the first cooling step to keep the casting or machine part warm at a constant temperature in the heat treatment furnace After passing through the primary warming step and the first warming step, the second temperature raising step of raising the temperature of the casting or mechanical parts with a temperature gradient of a certain temperature per hour in the heat treatment furnace, and maintaining the temperature in a state elevated to a certain temperature in the second heating step After passing through the tempering step and the tempering step, the secondary cooling step of rapidly cooling the casting or mechanical part in a heat treatment furnace and the second cooling step, the casting or the mechanical part is kept at a constant temperature in the heat treatment furnace 2 Including the tea warming step,
In the plurality of heat treatment furnaces, the power consumed in the first temperature raising step, the first cooling step, the first keeping warm step, the second temperature raising step, the second cooling step, and the second keeping warm step is collectively predetermined. A method for controlling the maximum power demand of a multiple heat treatment furnace, including controlling or blocking the time period of
The method of claim 1,
In the plurality of heat treatment furnaces, the power consumed in the first temperature raising step, the first cooling step, the first keeping warm step, the second temperature raising step, the second cooling step, and the second keeping warm step is partially predetermined. A method of controlling the maximum power demand of a multi-heat treatment furnace including adjusting or blocking over time.
The method of claim 1,
The first heating step, the first cooling step, the first warming step, the second temperature rising step, the second cooling step, and the second warming step in any one of the plurality of heat treatment furnaces. A method for controlling maximum demand for power in a multiple heat treatment furnace, comprising controlling or blocking electric power at a predetermined time in a batch.
The method of claim 1,
The first heating step, the first cooling step, the first warming step, the second temperature rising step, the second cooling step, and the second warming step in any one of the plurality of heat treatment furnaces. A method for controlling maximum power demand of a multi-heat treatment furnace, comprising controlling or cutting off electric power partially over a predetermined time.
The method of claim 1,
After checking the power state by sequencing the plurality of heat treatment furnaces, the first temperature raising step, the first cooling step, the first warming step, the second temperature raising step, the second cooling step, the second step of the heat treatment furnace sequentially A method for controlling maximum power demand of a multi-heat treatment furnace, comprising controlling or blocking the electric power required in the car keeping warm step at a predetermined time in a batch.
The method of claim 1,
After checking the power state by sequencing the plurality of heat treatment furnaces, the first temperature raising step, the first cooling step, the first warming step, the second temperature raising step, the second cooling step, the second step of the heat treatment furnace sequentially A method for controlling maximum power demand for a multi-heat treatment furnace, comprising partially controlling or blocking the electric power required in the car warming step for a predetermined time.

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