KR20210038077A - Gas pressure monitoring system for mold equipement based on n2 gas atmosphere - Google Patents

Abstract

The present invention relates to a gas pressure monitoring system for mold equipment based on a nitrogen gas atmosphere, comprising: a forming mold equipment unit having one or more forming molds; a nitrogen gas supply-discharge apparatus unit which is configured to supply nitrogen gas to the forming mold and discharges nitrogen gas from the forming mold; a gas pressure detection unit configured to detect the pressure value of nitrogen gas filling the forming mold; and a mold equipment monitoring apparatus unit configured to control the operation of the nitrogen gas supply-discharge apparatus nit, and to monitor the operation status of the forming mold equipment unit based on a detection signal from the gas pressure detection unit. The present invention is able to monitor for an error of the nitrogen atmosphere for each forming mold in the mold equipment performing a forming process in a nitrogen gas atmosphere with a high level of reliability, prevent a defective mold, and improve the overall operability of the mold equipment.

Description

Gas pressure monitoring system for mold facilities based on nitrogen gas atmosphere {GAS PRESSURE MONITORING SYSTEM FOR MOLD EQUIPEMENT BASED ON N2 GAS ATMOSPHERE}

The present invention relates to a gas pressure monitoring system of a mold facility based on a nitrogen gas atmosphere, and more particularly, a mold facility that performs a molding process in a nitrogen gas atmosphere reliably monitors an error in a nitrogen atmosphere for each mold to prevent mold defects and It relates to a gas pressure monitoring system of a mold facility based on a nitrogen gas atmosphere that improves the operability of the mold facility.

정도의 온도로 가열된 철강 소재를 금형으로 이동시켜 프레스를 이용하여 성형한 뒤, 금형 내에서 급속 냉각시키는 공법을 말한다. 즉, 핫스탬핑 공정은, 고온 성형과 담금질 냉각(Quenching)을 동시에 할 수 있어 강판 소재의 열변형을 최소화하고 밀폐된 금형 내에서 급랭함으로써 원소재를 초고강력강으로 변화시킨다. The hot stamping process is approximately 950

It refers to a method of moving a steel material heated to about a temperature to a mold, forming it using a press, and then rapidly cooling it in the mold. In other words, in the hot stamping process, high-temperature molding and quenching can be performed at the same time, thereby minimizing thermal deformation of the steel sheet material and rapidly cooling the material in a sealed mold to change the raw material into ultra-high-strength steel.

The hot stamping process includes a process of heat-treating the cooled molding to a predetermined temperature or less in a nitrogen gas atmosphere.

However, such a conventional mold facility based on a nitrogen gas atmosphere has a problem in that a defect of a molded product occurs because it cannot accurately detect a change in gas pressure due to leakage of gas filled inside the mold.

In addition, the conventional nitrogen gas atmosphere-based mold facility has a problem in that an operator or a manager cannot easily recognize information on whether or not the gas leaks.

Korean Registered Patent Publication No. 10-2000251 (registered on July 9, 2019) Korean Patent Application Publication No. 10-2018-0130118 (published on Dec. 7, 2018)

In solving the above problems, an object of the present invention is to reliably monitor errors in nitrogen atmosphere for each molding mold in a mold facility that performs a molding process in a nitrogen gas atmosphere to prevent mold defects and improve overall mold facility operability. It is to provide a gas pressure monitoring system for mold facilities based on nitrogen gas atmosphere.

In addition, it is an object of the present invention to provide a gas pressure monitoring system for a mold facility based on a nitrogen gas atmosphere, which can be easily attached and detached using a connection connector when a mold is changed, so that a change operation can be quickly performed.

In addition, it is an object of the present invention to provide a gas pressure monitoring system for a gas atmosphere-based mold facility that improves work stability and economics of the entire process by allowing workers or managers to easily recognize information on whether gas is leaking. Is in.

The gas pressure monitoring system of a mold facility based on a nitrogen gas atmosphere according to an embodiment of the present invention is configured to supply nitrogen gas to the molding mold and discharge nitrogen gas from the molding mold, a molding mold facility having one or more molding molds. A nitrogen gas supply-discharge device unit, a gas pressure detection unit configured to detect a pressure value of nitrogen gas to be filled in the molding mold, and a detection signal from the gas pressure detection unit controlling the operation of the nitrogen gas supply-discharge unit unit It is configured to include a mold equipment monitoring device unit configured to monitor the operation state of the molding mold equipment unit on the basis of.

In this case, the molding mold equipment unit may be configured to include one or more molding molds forming a space in which a molding object is placed, and a molding mold body in which the molding mold is detachably provided, and in this case, the molding mold It is preferable that the silver connection connector is provided so as to be mountable to the mold body.

Meanwhile, the nitrogen gas supply-discharge device unit includes a first nitrogen gas storage container provided on an outer side of the molding mold facility, a nitrogen gas supply pipe connecting the first nitrogen gas storage container and the molding mold, and the molding A nitrogen gas supply unit including a first pumping device provided to pump nitrogen gas into the mold, and a first opening/closing valve provided on the nitrogen gas supply pipe and controlling an opening or closing degree; And a second nitrogen gas storage container provided on the other side of the molding mold facility, a nitrogen gas discharge pipe connecting the second nitrogen gas storage container and the molding mold, and pumping nitrogen gas from the inside of the molding mold. It may be configured to include a second pumping device, and a nitrogen gas discharge device unit including a second opening and closing valve provided on the nitrogen gas discharge pipe to control the opening or closing degree.

In this case, it is preferable that the gas pressure detection unit is constituted by a digital pressure sensor provided in at least one of the molding mold.

In this case, the gas pressure detection unit is provided to detect a nitrogen gas pressure value inside the molding mold, and is adjacent to the molding mold and in an isolation space inside the molding mold body formed to be isolated from the inner space of the molding mold. It is preferable to be provided.

In addition, it is preferable that the gas pressure detection unit is configured to be capable of converting and outputting the detected result into an analog signal in connection with a printer control language (PLC).

On the other hand, the mold equipment monitoring device unit controls the operation of the first pumping device and the second pumping device to supply nitrogen gas to the inside of the molding mold or to discharge nitrogen gas from the inside of the molding mold according to a preset value. A pumping control unit configured to be configured to, a valve control unit configured to control the operation of the first on/off valve and the second on/off valve in interlocking with the pumping control unit, and a preset value by receiving a nitrogen gas pressure detection value from the gas pressure detection unit Compared with, it may be configured to include a gas pressure determination unit configured to determine whether the nitrogen gas is filled and whether the nitrogen gas leaks inside the molding mold.

In this case, the mold facility monitoring device may further include a status notification unit configured to receive the determination result of the gas pressure determination unit and output it in at least one of an audible notification and a visual notification.

In addition, the mold facility monitoring unit further includes a control environment setting unit configured to enable a change input of a system execution mode, a change input of a nitrogen pressure set value in the molding mold, and a change input of a leak determination set value of the gas pressure determination unit. It can be configured to include.

In addition, the mold facility monitoring device unit may further include a display unit configured to display a control state including a control state and a result of each unit.

As described above, the gas pressure monitoring system of the gas atmosphere-based mold facility according to the present invention prevents mold defects by reliably monitoring errors in the nitrogen atmosphere for each mold in the mold facility that performs the molding process in a nitrogen gas atmosphere. Improve the operability of the facility.

In addition, the gas pressure monitoring system of the gas atmosphere-based mold facility according to the present invention can be easily attached and detached using a connection connector when a molding mold is changed, so that a change operation can be performed quickly.

In addition, the gas pressure monitoring system of a mold facility based on a gas atmosphere according to the present invention improves work stability and economics of the entire process by allowing an operator or a manager to easily recognize information on whether or not a gas leaks.

1 is a block diagram schematically showing a gas pressure monitoring system of a gas atmosphere-based mold facility according to an embodiment of the present invention.
2 is a diagram showing an example of a test application of a gas pressure monitoring system of a gas atmosphere-based mold facility according to an embodiment of the present invention.
3 is a diagram illustrating a state in which a gas pressure detector is installed in FIG. 2.
FIG. 4 is a diagram illustrating a mold facility monitoring device that has been experimentally applied in the example of FIG.

In the present invention, the accompanying drawings may be shown as exaggerated expressions for the sake of discrimination and clarity from the prior art, and for the convenience of grasping the technology. In addition, terms to be described later are terms defined in consideration of functions in the present invention, and may vary according to the intentions or customs of users and operators, so the definition of these terms should be made based on the technical contents throughout the present specification. will be. On the other hand, the embodiments are only exemplary matters of the constituent elements presented in the claims of the present invention, and do not limit the scope of the present invention, and the scope of the rights should be interpreted based on the technical idea throughout the specification of the present invention. .

1 is a block diagram schematically showing a gas pressure monitoring system of a gas atmosphere-based mold facility according to an embodiment of the present invention, and FIG. 2 is a test of a gas pressure monitoring system of a gas atmosphere-based mold facility according to an embodiment of the present invention. FIG. 3 is a diagram illustrating an applied example, and FIG. 3 is a diagram illustrating a state in which a gas pressure detection unit is installed in FIG. 2, and FIG. 4 is a diagram illustrating a mold facility monitoring device experimentally applied in the example of FIG. 2.

The gas pressure monitoring system of a mold facility based on a nitrogen gas atmosphere according to an embodiment of the present invention includes a molding mold facility 100, a nitrogen gas supply-discharge device 200, a gas pressure detector 300, and a mold facility monitoring device. It is comprised of 400.

The molding mold equipment unit 100 is a configuration including one or more molding molds 110.

More specifically, the molding mold equipment unit 100 includes at least one molding mold 110 forming a space in which a molding object is placed, and a molding mold body 120 in which the molding mold 110 is detachably provided. ) Can be included.

In this case, the molding mold 110 has a sealed interior capable of filling gas, and may be provided with a cradle corresponding to the shape of the object to be molded.

In this case, the molding mold 110 is preferably provided to be mounted on the molding mold body 120 with a connection connector 101. That is, since the shape of the molding mold 110 can be changed according to the object to be molded, the mold change operation is quickly performed by configuring detachably to the molding mold body 120 via the connection connector 101. The technical effect that can be done will be pursued.

The molding mold installation unit 100 is structurally closely connected with the nitrogen gas supply-discharge device unit 200 and the gas pressure detection unit 300.

The nitrogen gas supply-discharge unit 200 supplies nitrogen gas to the molding mold 110, and when a predetermined process (eg, annealing heat treatment process) is completed, nitrogen gas from the molding mold 110 It is configured to discharge.

In this case, the nitrogen gas supply-discharge unit 200 may include a nitrogen gas supply unit 210 and a nitrogen gas discharge unit 220.

In this case, the nitrogen gas supply unit 210 includes a first nitrogen gas storage container 211, a nitrogen gas supply pipe 212, a first pumping device (not shown), and a first opening/closing valve 213 Can be configured.

The first nitrogen gas storage container 211 is provided on an outer side of the molding mold facility 100 and is configured to store nitrogen gas of a design capacity.

The nitrogen gas supply pipe 212 connects the first nitrogen gas storage container 211 and the molding mold 110 to form a nitrogen gas supply passage into the molding mold 110. The nitrogen gas supply pipe 212 is made of a tube diameter and a material for smooth flow and supply of nitrogen gas.

The first pumping device (not shown) is provided to pump nitrogen gas into the molding mold 110, is provided on the nitrogen gas supply pipe 212, and is controlled by a pumping control unit 410 to be described later. Nitrogen gas is pumped.

The first opening/closing valve 213 is provided on the nitrogen gas supply pipe 212, and the opening/closing or opening degree is controlled by the control of the valve controller 420, which will be described later.

Meanwhile, the nitrogen gas discharge device 220 includes a second nitrogen gas storage container 221, a nitrogen gas discharge pipe 222, a second pumping device (not shown), and a second opening/closing valve 223. Can be configured.

The second nitrogen gas storage container 221 is provided on the other side of the molding mold facility 100 and is configured to store nitrogen gas of a design capacity.

The nitrogen gas discharge pipe 222 connects the second nitrogen gas storage container 221 and the molding mold 110 to form a nitrogen gas discharge passage from the inside of the molding mold 110. The nitrogen gas discharge pipe 212 is made of a tube diameter and a material for smooth flow and supply of nitrogen gas.

The second pumping device (not shown) is provided to pump nitrogen gas from the inside of the molding mold 110, is provided on the nitrogen gas discharge pipe 222, and is controlled by a pumping control unit 410 to be described later. Nitrogen gas is pumped.

The second on-off valve 223 is provided on the nitrogen gas supply pipe 222, and the opening or closing or opening degree is controlled by the control of the valve controller 420 to be described later.

The gas pressure detection unit 300 is configured to detect a pressure value of nitrogen gas filled in the molding mold 110 by the nitrogen gas supply-discharge device unit 200.

In this case, the gas pressure detection unit 300 is preferably composed of a digital pressure sensor provided in one or more of the molding mold 110.

At this time, the gas pressure detection unit 300 is provided to detect a nitrogen gas pressure value inside the molding mold 110, and is adjacent to the molding mold 110 and the inner space of the molding mold 110 It is preferable that it is provided in an isolation space inside the molding mold body 120 that is formed to be isolated. Accordingly, the gas pressure detection unit 300 can be easily separated from the molding mold 110 to be replaced or repaired.

Meanwhile, the gas pressure detection unit 300 is preferably configured to be capable of converting and outputting the detected result into an analog signal in connection with a printer control language (PLC).

The mold equipment monitoring unit 400 controls the operation of the nitrogen gas supply-discharge unit 200 and monitors the operation state of the molding mold equipment based on a detection signal from the gas pressure detection unit 300 Is configured to

The mold facility monitoring device 400 may include the pumping control unit 410, the valve control unit 420, and a gas pressure determination unit 430. In addition, the mold facility monitoring device 400 may include at least one of a status notification unit 440, a control environment setting unit 450, a display unit 460, a workplace monitoring unit 470, and a power control unit 480. It may be configured to further include one or more.

The pumping control unit 410 includes the first pumping device (not shown) to supply nitrogen gas into the molding mold 110 or discharge nitrogen gas from the molding mold 110 according to a preset value, and It is configured to control the operation of the second pumping device (not shown).

In this case, the pumping control unit 410 may be implemented in a manual control mode and an automatic control mode, and in the manual control mode, the first pumping device (not shown) and the second pumping device ( The operation of the first pumping device (not shown) and the second pumping device (not shown) may be automatically controlled according to a preset control algorithm in the automatic control mode.

The valve control unit 420 is configured to control the operation of the first on/off valve 213 and the second on/off valve 223 in connection with the pumping control unit 410.

In this case, the valve control unit 420 may be configured to adjust the amount of nitrogen gas supplied into the individual molding mold 110 and to control the amount of nitrogen gas discharged from the inside of the individual molding mold 110. .

In this case, the valve control unit 420 may be implemented in a manual control mode and an automatic control mode, similar to the pumping control unit 410, so that the first opening/closing valve 213 is performed by an operator's manual operation in the manual control mode. And the operation of the second on/off valve 223 is controlled, and in the automatic control mode, the operation of the first on/off valve 213 and the second on/off valve 223 is automatically controlled according to a preset control algorithm. I can.

The gas pressure determination unit 430 is provided with a nitrogen gas pressure detection value inside the individual molding mold 110 from the gas pressure detection unit 300 and compares it with a preset value to fill the nitrogen gas inside the molding mold 110 It is configured to determine the state and whether nitrogen gas leaks.

More specifically, the gas pressure determination unit 430, when nitrogen gas is less than a preset filling pressure value based on the nitrogen gas filling pressure value of the individual molding mold 110 detected through a plurality of digital pressure sensors after the filling of nitrogen gas is completed. It may be configured to determine as a gas leak.

Accordingly, the gas pressure monitoring system of the gas atmosphere-based mold facility according to the embodiment of the present invention reliably monitors the error of the nitrogen atmosphere for each molding mold in the mold facility that performs the molding process in a nitrogen gas atmosphere, thereby ultimately preventing mold defects. Prevent and improve the operability of the overall mold equipment.

The status notification unit 440 receives the determination result of the gas pressure determination unit 430 and receives at least one of an audible notification (eg, a buzzer sound, a guide sound) and a visual notification (eg, a warning lamp). It is configured to perform a function of outputting in a notification manner. That is, the status notification unit 440 performs a function of recognizing information on whether a nitrogen gas leaks to a user or a worker.

The status notification unit 400 may be implemented anywhere on a work site, and in particular, when configured to provide a visual notification, a plurality of colors such as green, yellow, red, etc., to notify the degree of leakage of nitrogen gas in stages. A lighting method using can be used.

The control environment setting unit 450 inputs a change in a system execution mode, a change input of a nitrogen pressure set value (initial filling pressure value) in the molding mold, and a set value (reference value) to determine whether the gas pressure determination unit 430 leaks. ) Is configured to enable change input.

The display unit 460 is configured to display a control state including a control state and a result of each unit. That is, the display unit 460 includes the pumping control unit 410, the valve control unit 420, the gas pressure determination unit 430, the status notification unit 440, and the control environment setting unit 450. It may be configured to display a control state, such as a control situation and a result of determining whether the environment and nitrogen gas leak.

The work site monitoring unit 470 may be configured to display one or more images captured by a camera installed on the work site or a photographing means such as CCTV in real time.

The power control unit 480 may be configured to control ON/OFF of the entire system.

As described above, the gas pressure monitoring system of the gas atmosphere-based mold facility according to the present invention prevents mold defects by reliably monitoring errors in the nitrogen atmosphere for each mold in the mold facility that performs the molding process in a nitrogen gas atmosphere. It improves the operability of the facility, and when the mold is changed, it can be easily attached and detached using a connection connector, so that the change can be performed quickly, and information on whether there is a gas leak can be provided by the operator or the manager. By making it easy to recognize, it improves work stability and economics of the whole process.

As described above, the present invention has been described with reference to the embodiment shown in the drawings, but this is only illustrative, and various modifications and equivalent other embodiments are possible based on common knowledge in the field to which the technology pertains. You have to understand. Therefore, the true technical protection scope of the present invention is based on the claims to be described below, and should be determined based on the specific contents of the invention.

The present invention relates to a gas pressure monitoring system of a mold facility based on a nitrogen gas atmosphere, and can be used in an industrial field related to a mold facility.

100: molding mold facility
101: connection connector
110: molding mold
120: molding mold body
200: nitrogen gas supply-discharge device unit
210: nitrogen gas supply unit
211: first nitrogen gas storage container
212: nitrogen gas supply pipe
213: first on-off valve
220: nitrogen gas discharge device unit
221: second nitrogen gas storage container
222: nitrogen gas discharge pipe
223: second on-off valve
300: gas pressure detection unit
400: mold facility monitoring device unit
410: pumping control section
420: valve control unit
430: gas pressure determination unit
440: status notification unit
450: control environment setting unit
460: display unit
470: Work site monitoring unit
480: power control

Claims (10)

Molding mold equipment unit having one or more molding molds;
A nitrogen gas supply-discharge device configured to supply nitrogen gas to the molding mold and discharge nitrogen gas from the molding mold;
A gas pressure detection unit configured to detect a pressure value of nitrogen gas to be filled in the molding mold; And
A mold equipment monitoring device configured to control an operation of the nitrogen gas supply-discharge device unit and to monitor an operation state of the molding mold equipment unit based on a detection signal from the gas pressure detection unit;
Gas pressure monitoring system of a mold facility based on a nitrogen gas atmosphere comprising a.
The method of claim 1, wherein the molding mold equipment unit,
At least one molding mold forming a space in which a molding object is placed, and a molding mold main body in which the molding mold is detachably provided,
The molding mold is a gas pressure monitoring system of a mold facility based on a nitrogen gas atmosphere, characterized in that it is provided to be mounted on the molding mold body as a connection connector.
The method of claim 1, wherein the nitrogen gas supply-discharge device unit,
A first nitrogen gas storage container provided on an outer side of the molding mold facility, a nitrogen gas supply pipe connecting the first nitrogen gas storage container and the molding mold, and a first provided to pump nitrogen gas into the molding mold. 1 a nitrogen gas supply unit including a pumping device and a first opening/closing valve provided on the nitrogen gas supply pipe and controlling an opening or closing degree; And
A second nitrogen gas storage container provided on the other side of the molding mold equipment unit, a nitrogen gas discharge pipe connecting the second nitrogen gas storage container and the molding mold, and a first provided to pump nitrogen gas from the inside of the molding mold 2 a nitrogen gas discharge device including a pumping device, and a second opening/closing valve provided on the nitrogen gas discharge pipe and controlling an opening or closing degree;
Gas pressure monitoring system of a nitrogen gas atmosphere-based mold facility comprising a.
The method of claim 1, wherein the gas pressure detection unit,
Gas pressure monitoring system of a nitrogen gas atmosphere-based mold facility, characterized in that consisting of a digital pressure sensor provided in the molding mold at least one.
The method of claim 4, wherein the gas pressure detection unit,
Nitrogen gas, characterized in that it is provided to detect a pressure value of nitrogen gas inside the molding mold, and is provided in an isolation space inside the molding mold body that is adjacent to the molding mold and formed to be isolated from the inner space of the molding mold Gas pressure monitoring system for atmosphere-based mold facilities.
The method of claim 4, wherein the gas pressure detection unit,
A gas pressure monitoring system of a mold facility based on a nitrogen gas atmosphere, characterized in that it is configured to convert and output the detected result into an analog signal in connection with a PLC (Printer Control Language).
The method of claim 3, wherein the mold equipment monitoring device,
A pumping control unit configured to control operations of the first pumping device and the second pumping device to supply nitrogen gas into the molding mold or discharge nitrogen gas from the molding mold according to a preset value;
A valve control unit configured to control the operation of the first on/off valve and the second on/off valve in connection with the pumping control unit; And
A gas pressure determination unit configured to receive a nitrogen gas pressure detection value from the gas pressure detection unit and compare it with a preset value to determine a state of nitrogen gas filling in the molding mold and whether a nitrogen gas leaks;
Gas pressure monitoring system of a nitrogen gas atmosphere-based mold facility comprising a.
The method of claim 7, wherein the mold equipment monitoring device,
A status notification unit configured to receive the determination result of the gas pressure determination unit and output an audible notification and a visual notification in at least one notification method;
Gas pressure monitoring system of a nitrogen gas atmosphere-based mold facility, characterized in that it further comprises.
The method of claim 7, wherein the mold equipment monitoring device,
A control environment setting unit configured to enable a change input of a system execution mode, a change input of a nitrogen pressure set value in the molding mold, and a change input of a leak determination set value of the gas pressure determination unit;
Gas pressure monitoring system of a nitrogen gas atmosphere-based mold facility, characterized in that it further comprises.
The method of claim 7, wherein the mold equipment monitoring device,
A display unit configured to display a control state including a control state and a result of each unit;
Gas pressure monitoring system of a nitrogen gas atmosphere-based mold facility, characterized in that it further comprises.

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