KR102162916B1 - Apparatus and method for additive manufacturing high strength materials for punch dies - Google Patents

Abstract

In the punch mold high-strength material lamination apparatus of the present invention, in the punch mold high-strength material lamination apparatus for manufacturing a punch mold in which a base portion and a processing portion having a strength greater than that of the base portion are formed on one side of the base portion, the punch mold is A fixed frame fixedly disposed; An induction heating coil provided on one side of the fixed frame to preheat the punch mold disposed on the fixed frame, and disposed in a cylindrical shape along the outer circumference of the punch mold to apply heat to the punch mold, and the induction heating coil Preheating unit including a coil control unit for controlling the; And a 3D printer that is provided to be movable on one side of the fixed frame, supplies a metal powder material to the punch mold, and directly melts the punch mold and the metal powder material by irradiating a laser beam to laminate the metal material. Include.
According to the apparatus and method for laminating a high-strength material for a punch mold according to the present invention, a processing portion having a strength greater than that of the base portion is formed in the punch mold, so that a post-treatment process of a component whose strength is enhanced by a hot stamping process is possible, and Accordingly, damage and damage to the punch mold can be prevented and the efficiency of use can be improved. In addition, by preheating the punch mold before laminating the metal powder material using the preheating unit, the cooling rate and the solidification rate are controlled to prevent lamination defects, thereby improving lamination.

Description

Apparatus and method for additive manufacturing high strength materials for punch dies}

The present invention relates to a punch mold high-strength material lamination apparatus for manufacturing a punch mold with enhanced strength and capable of piercing and trimming a high-strength object manufactured by a hot stamping process.

In general, the hot stamping process refers to a method of rapidly cooling a steel material heated to a temperature of about 950°C using a press and then rapidly cooling. That is, in the above-described hot stamping process, a high-strength component can be manufactured by heating an object to a temperature with good formability to increase workability and rapidly cooling it using a cooling channel. Parts processed by the above-described hot stamping have been shown to increase the strength by about twice as much as that of conventional materials and increase in weight effect by about 25%. Therefore, the hot stamping process can maintain high safety with a small amount of material, thereby reducing manufacturing costs, as well as improving fuel economy due to weight reduction, and has the advantage of enjoying a chain effect such as environmental effects due to fuel reduction.

However, the above-described hot stamping technique has a disadvantage in that the strength of the component is increased due to the hot stamping process, and post-treatment processes such as piercing or trimming of the component become difficult. Therefore, most of the post-treatment processes after hot stamping are resolved using laser equipment, and the use of laser equipment causes disadvantages in terms of production efficiency and production cost.

In order to improve the shortcomings of the laser equipment, a press process may be introduced as a post-treatment process of the hot stamping technology, but a high-strength punch mold is required to pierce or trim parts with increased strength due to the hot stamping process. do. In addition, parts that have increased strength through the hot stamping process are easily damaged by the strong reaction force generated from the material, resulting in poor surface quality and dimensional accuracy of the product, and shortening the life of the punch mold. Damage to shear punch molds as described above includes chipping, cracking, gross fracture, and galling, and appears because the hardness, toughness, and wear resistance of the mold material are not in harmony. .

Therefore, in order to prevent damage to the punch mold, heat treatment and nitriding treatment are applied to the punch mold, followed by coating to create a surface layer of another element, or heat treatment as a whole. However, in the case of surface treatment, if the coating is deepened, the cost increases, and if the punch mold is heat treated as a whole, there is a disadvantage in that the punch mold is subjected to deep and strong heat treatment, resulting in damage and thus lowering the use efficiency.

As a technique for post-treatment processing such as piercing processing or trim processing of a conventional hot stamped material, Korean Patent Application Publication No. 10-2014-0077005 has been disclosed.

The present invention was created to solve the above-described problems, and a post-treatment process of parts with increased strength by a hot spamping process is possible, and a punch mold high strength material lamination apparatus capable of providing a punch mold with improved use efficiency There is a purpose to provide.

According to the punch mold high-strength material lamination apparatus of the present invention for achieving the above object, a punch mold for manufacturing a punch mold having a base portion and a processing portion having a strength greater than that of the base portion is formed on one side of the base portion. A material stacking apparatus comprising: a fixed frame in which a punch mold is fixedly disposed on an upper surface; An induction heating coil provided on one side of the fixed frame to preheat the punch mold disposed on the fixed frame, and disposed in a cylindrical shape along the outer circumference of the punch mold to apply heat to the punch mold, and the induction heating coil Preheating unit including a coil control unit for controlling the; And a 3D printer that is provided to be movable on one side of the fixed frame, supplies a metal powder material to the punch mold, and directly melts the punch mold and the metal powder material by irradiating a laser beam to laminate the metal material. Include.

Here, the preheating unit includes an induction heater disposed on one side of the punch mold to apply heat to the punch mold to heat treatment, a heater insulating material provided along the outer circumference of the induction heater, and disposed on the other side of the punch mold Thus, it may include an auxiliary induction heater that auxiliaryly applies heat to the punch mold, and a heating control unit that controls the induction heater and the auxiliary induction heater.

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In addition, the 3D printer unit includes a nozzle frame provided to be movable on one side of the fixed frame, a powder supply unit for supplying a metal powder material to the punch mold by forming a powder flow path inside the nozzle frame, and A laser flow path is formed inside, a laser section that directly melts the metal powder material supplied from the punch mold and the powder supply section by irradiating a laser beam, and a shielding gas flow path is formed inside the nozzle frame. The furnace may include a shielding gas part for shielding a part melted from the laser part from the outside by supplying a shielding gas.

On the other hand, according to the punch mold high strength material laminating apparatus of the second embodiment of the present invention, a punch mold high strength material laminating apparatus for manufacturing a punch mold in which a base portion and a processing portion having a strength greater than that of the base portion are formed on one side of the base portion. In the above, the fixed frame on which the punch mold is fixedly disposed on the upper surface; A 3D printer unit provided to be movable on one side of the fixed frame, supplying a metal powder material to the punch mold, and laminating the metal material by directly melting the punch mold and the metal powder material by irradiating a laser beam; And a preheating section for controlling the laser beam of the 3D printer to preheat the punch mold before laminating the metal material in the 3D printer, and for selecting a preheating condition of the punch mold, and a temperature for sensing the temperature of the punch mold. It includes a preheating control unit including a detection sensor.

Here, the 3D printer unit includes a nozzle frame provided to be movable on one side of the fixed frame, a powder supply unit for supplying a metal powder material to the punch mold by forming a powder flow path inside the nozzle frame, and A laser flow path is formed inside, a laser part that directly melts the metal powder material supplied from the punch mold and the powder supply part by irradiating a laser beam, and a shielding gas flow path is formed inside the nozzle frame. It may include a shielding gas unit for supplying a shielding gas through a flow path to shield a portion melted from the laser unit from the outside.

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In addition, it is preferable that the preheating control unit preheats the punch mold by controlling the wavelength of the laser beam of the 3D printer in response to the preheating condition selected by the preheating unit and the temperature of the punch mold detected by the temperature sensor. .

On the other hand, according to the punch mold high strength material lamination method according to the third embodiment of the present invention, a punch mold high strength material lamination for manufacturing a punch mold in which a base portion and a processing portion having a strength greater than that of the base portion are formed on one side of the base portion. An apparatus, comprising: a pre-lamination processing step of determining a range, shape, and material of a laminated portion of a metal material to be laminated on a punch mold; A punch mold preheating step of preheating a punch mold for stacking the stacked portions determined in the stacking pretreatment step; And 3D printing in which a metal powder material is supplied to the punch mold in response to the shape of the laminate determined in the pre-lamination step, and the metal material is laminated by directly melting the punch mold and the metal powder material by irradiating a laser beam. It includes a lamination step.

Here, the pre-lamination step includes a punch mold stress analysis step of analyzing the stress distribution of the punch mold, and the range of the laminated portion of the metal material to be laminated on the punch mold in response to the stress distribution of the punch mold analyzed in the punch mold stress analysis step. It may include a stacking range selection step of determining a stacking range, and a stacking shape forming step of forming a shape of a stacking portion to be stacked on the punch mold in correspondence with the stacking portion range selected in the stacking range selection step.

In addition, in the preheating of the punch mold, it is preferable to preheat the punch mold using induction heating.

In addition, the punch mold preheating step may include a preheating temperature control step of controlling a temperature for preheating the punch mold, and a preheating speed control step of controlling a speed of preheating the punch mold.

In addition, in the punch mold preheating step, it is preferable to preheat the punch mold to 200 degrees or more.

According to the apparatus and method for laminating a high-strength material for a punch mold according to the present invention, a processing portion having a strength greater than that of the base portion is formed in the punch mold, so that a post-treatment process of a component whose strength is reinforced by a hot stamping process is possible. Accordingly, damage and damage to the punch mold can be prevented and the efficiency of use can be improved.

In addition, by preheating the punch mold before laminating the metal powder material using the preheating unit, the cooling rate and the solidification rate are controlled to prevent lamination defects, thereby improving lamination.

In addition, by partially laminating the metal powder material for forming the processing part on the punch mold using the 3D printer, the mechanical properties of the punch mold are improved and the manufacturing efficiency is high, and the stress distribution of the punch mold is responded to through the pre-lamination step to achieve a suitable shape. By forming the laminated portion, manufacturing efficiency can be increased.

In addition, the preheating control unit controls the laser beam of the 3D printer to preheat the punch mold to allow preheating and lamination at the same time, and the preheating and lamination function of the punch mold is possible with one component, simplifying the device and increasing the efficiency. have.

In addition, a customized punch mold having the required strength can be obtained by partially controlling and laminating the areas requiring high strength on the punch mold.

1 is a perspective view showing a punch mold high strength material laminating apparatus according to a first embodiment of the present invention,
FIG. 2 is a perspective view showing a 3D printer part of the punch mold high strength material lamination apparatus shown in FIG. 1 in a cross-sectional perspective view;
3 is a side view showing a 3D printer in a cross-sectional view of the punch mold high strength material lamination apparatus shown in FIG. 1;
4 is a perspective view showing another embodiment of a preheating unit of the punch mold high strength material lamination apparatus shown in FIG. 1;
5 is a perspective view showing a cross-sectional perspective view showing a state in which a 3D printer unit of a punch mold high strength material laminating apparatus according to a second embodiment of the present invention preheats a punch mold;
6 is a flow chart showing a method for laminating a punch mold high strength material according to a third embodiment of the present invention;
7 is a flow chart showing a pre-lamination pre-treatment step of the method for laminating the punch mold high strength material shown in FIG. 6;
8 is a flow chart showing a punch mold preheating step of the punch mold high strength material lamination method shown in FIG.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the specification and claims should not be construed as being limited to their usual or dictionary meanings, and the inventors appropriately explain the concept of terms in order to explain their own invention in the best way. Based on the principle that it can be defined, it should be interpreted as a meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention, and do not represent all the technical ideas of the present invention, so at the time of application, they are equivalent to It should be understood that there may be variations.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 to 4, the punch mold high-strength material lamination apparatus 10 according to an embodiment of the present invention is a punch mold for shearing a part whose strength is enhanced by a hot stamping process, such as piercing or trim processing ( In order to manufacture 1), the punch mold (1) includes a base portion (1a) and a processing portion (1b) having a strength greater than that of the base portion (1a) on one side of the base portion (1a). Is formed. That is, the punch mold high-strength material laminating device 10 forms a processing portion 1b made of a high-strength material having a strength greater than that of the base portion 1a on the base portion 1a of the punch mold 1 A punch mold (1) capable of piercing or trimming high-strength parts can be manufactured. To this end, the punch mold high-strength material stacking device 10 may include a fixed frame 100, a preheating unit 200, and a 3D printer unit 300.

The fixing frame 100 is for fixing the punch mold 1, and the punch mold 1 is fixedly disposed on the upper surface. The fixing frame 100 may have a plate shape so that the punch mold 1 is seated on the upper surface, and a plurality of fixing chucks are provided on the fixing frame 100 to the outside circumference of the punch mold 1. By arranging a plurality of fixed chucks, the punch mold 1 may be fixedly disposed on the upper surface of the fixed frame 100.

The preheating part 200 is for preheating the base part 1a of the punch mold 1, and is provided on one side of the fixing frame 100, and the punch mold 1 disposed on the fixing frame 100 Can be preheated. In other words, the preheating unit 200 is a base unit (1a) by preheating the metal powder material 311 in the 3D printer unit 300 to be described later by laminating the laminated portion (1c) on the base unit (1a). When forming, it is possible to improve the lamination property by preventing heat shrinkage from occurring. The preheating unit 200a, which is the first embodiment of the preheating unit 200, includes an induction heater 210, a heater insulation 220, the auxiliary induction heater 230, the heating control unit 240, and a temperature sensor. (270) may be included.

The induction heater 210 is a high-frequency induction heater, and may generate heat in the coil by electromagnetic induction to preheat the base portion 1a. That is, the induction heater 210 is disposed on one side of the punch mold 1 to apply heat to the punch mold 1 to preheat the base portion 1a. In addition, the induction heater 210 is preferably spaced apart from one side of the outer surface of the punch mold (1).

The heater insulating material 220 is provided along the outer circumference of the induction heater 210.

The auxiliary induction heater 230 is for auxiliary heat application when preheating the punch mold 1, and is disposed to be spaced apart from the other side of the outer surface of the mold punch 1 to the base portion 1a. Heat is applied auxiliary. 1 to 4, the auxiliary induction heater 323 is illustrated as a high-frequency induction heater using a coil, but the present invention is not limited thereto, and is applied to apply auxiliary heat to the punch mold 1 using laser light. You can also make it. The auxiliary induction heater using the laser light forms a laser light by using an optical means such as an axicon lens, an optical vortex phase plate, or a galvano scanner. It is preferable to apply heat auxiliary to the punch mold (1).

The heating control unit 240 controls the induction heater 210 and the auxiliary induction heater 230.

The heating control unit 240 controls the induction heater 210 and the auxiliary induction heater 230 according to the preheating condition of the punch mold 1. The heating control unit 240 may control a preheating time, a preheating temperature, a preheating holding time, etc. for the induction heater 210 and the auxiliary induction heater 230 to preheat the base unit 1a, and the punch By controlling the preheating time, preheating temperature, preheating maintenance time, etc. in response to the size and shape of the laminated part lc to be formed on the mold 1 and the punch mold 1, the laminated part lc can be properly laminated. I can.

Meanwhile, FIG. 4 shows a preheating unit 200b, which is another embodiment of the preheating unit 200, wherein the preheating unit 200b includes an induction heating coil 250, the coil control unit 260, and the temperature sensing sensor. (270) may be included.

The induction heating coil 250 is provided along the outer circumference of the punch mold 1 and transfers heat to the base portion 1a. The induction heating coil 250 is a high-frequency induction heater, and may generate heat to the coil by electromagnetic induction to apply heat to the punch mold 1 to preheat the base portion 1a. The induction heating coil 250 is disposed in a cylindrical shape along the outer circumference of the punch mold 1 to preheat the base portion 1a, and the induction heating coil 250 is formed in a cylindrical shape, so that the surrounding air By blocking contact with the punch mold (1), it is possible to simultaneously have the effect of preventing oxidation and insulation.

The coil control unit 260 controls the induction heating coil 250 according to the preheating condition of the punch mold 1. The coil control unit 260 may control a preheating time, a preheating temperature, a preheating holding time, etc. for the induction heating coil 250 to preheat the base unit 1a, and the punch mold 1 and the punch mold The laminated part lc may be properly laminated by controlling a preheating time, a preheating temperature, a preheating maintenance time, etc. in response to the size and shape of the laminated part lc to be laminated on (1).

Meanwhile, the temperature sensor 270 senses the temperature of the punch mold 1. That is, the temperature sensor 270 is provided on one side of the punch mold 1 to detect the temperature of the punch mold 1 preheated by the preheating parts 200a and 200b, and the temperature sensor When the heating control unit 240 and the coil control unit 260 control the preheating of the punch mold 1 by sensing the temperature of the punch mold 1, the temperature of the base unit la In response, automatic control is possible and efficiency can be improved.

The 3D printer unit 300 is for forming a layered portion 1c by laminating a metal powder material 311 on one side of the base portion 1a, and uses a 3D printing technology using a Directed Energy Deposition (DED) method. Use. The 3D printer unit 300 is provided to be movable on one side of the fixed frame 100, supplies a metal powder material 311 to one side of the base unit 1a, and irradiates a laser beam 321 to the The metal material may be laminated by directly melting the punch mold 1 and the metal powder material 311. At this time, the shape of the lamination unit 1c stacked on the base unit 1a using the 3D printer unit 300 may be appropriately changed and applied according to the shape, purpose, size, etc. of the punch mold 1 . The 3D printer unit 300 may include a nozzle frame 301, the powder supply unit 310, the laser unit 320, and the shielding gas unit 330.

The nozzle frame 301 is provided to be movable on one side of the fixed frame 100 in an inverted conical shape. The nozzle frame 301 is formed of a powder flow passage 312, a laser flow passage 322, and a shielding gas flow passage 332 to be described later, and the metal powder from one side of the nozzle frame 301 to the other side. The material 311, the laser beam 321, and the shielding gas 331 may move, and the metal powder material 311, the laser beam 321, and the shielding gas 331, etc. It may be sprayed to the other side of 301 and supplied to one side of the preheated base portion 1a.

The powder supply unit 310 is for supplying the metal powder material 311 to the punch mold 1, and may include a powder passage 312 and a powder frame 313.

The powder flow path 312 is formed inside the nozzle frame 301, and the metal powder material 311 is formed to move from one side to the other side along the longitudinal direction of the nozzle frame 301. In addition, it is preferable that the powder flow path 312 is formed in a cylindrical shape whose circumference becomes smaller from one side to the other side as the nozzle frame 301 is formed in an inverted cone shape. That is, the powder flow passage 312 may supply the metal powder material 311 to one side of the punch mold 1 by receiving the metal powder material 311 from one side and discharging the metal powder material 311 to the other side. At this time, the metal powder material 311 supplied through the powder flow path 312 is a high strength metal powder material 311 having a strength greater than that of the base portion 1a of the punch mold 1, and molybdenum It is preferable that it is a high-speed tool steel powder material or a high-strength cold-worked tool steel powder containing alloying elements such as (Mo), tungsten (W), vanadium (V), and the like. In addition, a coaxial powder gas flow path is further formed on one side of the powder flow path 312, and by supplying the coaxial powder gas to the powder flow path 312, the supply of the metal powder material 311 may be assisted. . In order to smoothly supply the metal powder material 311, components such as a coaxial powder feeder and a powder feed controller may be further included, but this is a known technique and a detailed description thereof will be omitted herein.

The powder frame 313 is for accommodating the metal powder material 311 and is provided on one side of the nozzle frame 301. That is, the powder frame 313 may accommodate the metal powder material 311 therein, and communicate with the powder flow channel 312 to supply the metal powder material 311 to the powder flow channel 312.

The laser unit 320 is for irradiating the laser beam 321 to the punch mold 1, and is supplied from the punch mold 1 and the powder supply unit 310 by irradiating the laser beam 321 The metal powder material 311 is melted directly. To this end, a laser flow path 322 is formed inside the nozzle frame 301, and a laser beam 321 may be irradiated along the laser flow path 322. The laser flow path 322 is preferably formed to pass through the center of the nozzle frame 301, and the laser beam 321 along the laser flow path 322 from one side of the nozzle frame 301 to the other side Can be investigated. The laser beam 321 directly melts the metal powder material 311 supplied from the punch mold 1 and the powder supply unit 310 to form a lamination unit lc on one side of the base unit 1a. Let it. That is, by supplying the metal powder material 311 through the powder supply unit 310 to the base portion 1a on which the stacking portion lc is to be formed, and simultaneously irradiating the laser beam 321, the base portion By melting (1a) and the metal powder material 311 to create a molten pool, the laminated portion (lc) may be formed. At this time, by preheating the base portion 1a by the preheating portion 200, the cooling rate and the solidification rate of the stacked portion 1c may be lowered, thereby preventing the occurrence of heat shrinkage. That is, by preheating the base portion (1a) by the preheating portion (200), the stackability of the punch mold (1) is improved, and a high-speed tool steel powder material or high strength having a strength greater than that of the base portion (1a) Even if the metal powder material 311 of cold-rolled tool steel powder is laminated, it is possible to improve manufacturing efficiency by preventing defects such as cracks from occurring between the base portion la and the laminated portion lc.

Meanwhile, the laser unit 320 may inject a process gas along the laser flow path 322 so that a process gas is injected around the laser beam 321 to be irradiated together with the laser beam 321. It is possible to prevent oxidation of the molten pool melted by the laser beam 321 by the process gas. In order to smoothly irradiate the laser beam 321, an optical means for irradiating the laser beam 321, a coaxial gas portion for injecting a process gas, etc. may be further included, but this is a known technique and a detailed description thereof is omitted here. Do it.

The shielding gas part 330 is a shielding gas 331 for preventing oxidation of the metal powder material 311 of the punch mold 1 and the laminated part lc due to heat generated by the laser beam 321. ) To supply. To this end, a shielding gas flow path 332 is formed inside the nozzle frame 301, and the shielding gas 331 may be supplied through the shielding gas flow path 332. That is, the shielding gas flow path 332 is preferably formed in the inside of the nozzle frame 301 to the outside of the powder flow path 312 and spaced apart from the powder flow path 312, and the shielding gas 331 It may move from one side of the nozzle frame 301 to the other side along the shielding gas flow path 332 and be sprayed to the outside of the stacking part lc. That is, the shielding gas 331 is discharged to the other side of the nozzle frame 301, so that the shielding gas () to the outside of the punch mold 1 and the stacking part lc melted by the laser beam 321 Since 331) can be supplied continuously, oxidation can be prevented by shielding the melting part from the outside. The shielding gas 331 is an inert gas or a translucent gas, preferably an argon gas (Ar), a helium (He) mixed gas, etc., and a shielding gas frame for accommodating the shielding gas 331 may be further provided, This is a known technique and a detailed description thereof will be omitted here.

Hereinafter, the punch mold high-strength material laminating apparatus 20 according to the second embodiment of the present invention will be described with reference to FIG. 5. Here, the same reference numerals shown in FIGS. 1 to 4 are the same members having the same configuration and function, and thus a repetitive description will be omitted. The punch mold high-strength material laminating device 20 includes a fixed frame 100, a 3D printer unit 300, and a preheating control unit 400.

The fixing frame 100 is for fixing the punch mold 1, and the punch mold 1 is fixedly disposed on the upper surface. The fixing frame 100 may have a plate shape so that the punch mold 1 is seated on the upper surface, and a plurality of fixing chucks are provided on the fixing frame 100 to the outside circumference of the punch mold 1. By arranging a plurality of fixed chucks, the punch mold 1 may be fixedly disposed on the upper surface of the fixed frame 100.

The 3D printer unit 300 is for forming a layered portion 1c by laminating a metal powder material 311 on one side of the base portion 1a, and uses a 3D printing technology using a Directed Energy Deposition (DED) method. Use. The 3D printer unit 300 is provided to be movable on one side of the fixed frame 100, supplies a metal powder material 311 to one side of the base unit 1a, and irradiates a laser beam 321 to the The metal material may be laminated by directly melting the punch mold 1 and the metal powder material 311. At this time, the shape of the lamination unit 1c stacked on the base unit 1a using the 3D printer unit 300 may be appropriately changed and applied according to the shape, purpose, size, etc. of the punch mold 1 . The 3D printer unit 300 may include a nozzle frame 301, the powder supply unit 310, the laser unit 320, and the shielding gas unit 330.

The nozzle frame 301 is provided to be movable on one side of the fixed frame 100 in an inverted conical shape. The nozzle frame 301 is formed of a powder flow passage 312, a laser flow passage 322, and a shielding gas flow passage 332 to be described later, and the metal powder from one side of the nozzle frame 301 to the other side. The material 311, the laser beam 321, and the shielding gas 331 may move, and the metal powder material 311, the laser beam 321, and the shielding gas 331, etc. It may be sprayed to the other side of 301 and supplied to one side of the base portion 1a.

The powder supply unit 310 is for supplying the metal powder material 311 to the punch mold 1, and may include a powder passage 312 and a powder frame 313.

The powder flow path 312 is formed inside the nozzle frame 301, and the metal powder material 311 is formed to move from one side to the other side along the longitudinal direction of the nozzle frame 301. In addition, it is preferable that the powder flow path 312 is formed in a cylindrical shape whose circumference becomes smaller from one side to the other side as the nozzle frame 301 is formed in an inverted cone shape. That is, the powder flow passage 312 may supply the metal powder material 311 to one side of the punch mold 1 by receiving the metal powder material 311 from one side and discharging the metal powder material 311 to the other side. At this time, the metal powder material 311 supplied through the powder flow path 312 is a high strength metal powder material 311 having a strength greater than that of the base portion 1a of the punch mold 1, and molybdenum It is preferable that it is a high-speed tool steel powder material or a high-strength cold-worked tool steel powder containing alloying elements such as (Mo), tungsten (W), vanadium (V), and the like. In addition, a coaxial powder gas flow path is further formed on one side of the powder flow path 312, and by supplying the coaxial powder gas to the powder flow path 312, the supply of the metal powder material 311 may be assisted. . In order to smoothly supply the metal powder material 311, components such as a coaxial powder feeder and a powder feed controller may be further included, but this is a known technique and a detailed description thereof will be omitted herein.

The powder frame 313 is for accommodating the metal powder material 311 and is provided on one side of the nozzle frame 301. That is, the powder frame 313 may accommodate the metal powder material 311 therein, and communicate with the powder flow channel 312 to supply the metal powder material 311 to the powder flow channel 312.

The laser unit 320 is for irradiating the laser beam 321 to the punch mold 1, and is supplied from the punch mold 1 and the powder supply unit 310 by irradiating the laser beam 321 The metal powder material 311 is melted directly. To this end, a laser flow path 322 is formed inside the nozzle frame 301, and a laser beam 321 may be irradiated along the laser flow path 322. The laser flow path 322 is preferably formed to pass through the center of the nozzle frame 301, and the laser beam 321 along the laser flow path 322 from one side of the nozzle frame 201 to the other Can be investigated. The laser beam 321 directly melts the metal powder material 311 supplied from the punch mold 1 and the powder supply unit 310 to form a lamination unit lc on one side of the base unit 1a. Let it. That is, by supplying the metal powder material 311 through the powder supply unit 310 to the base portion 1a on which the stacking portion lc is to be formed, and simultaneously irradiating the laser beam 321, the base portion By melting (1a) and the metal powder material 311 to generate a molten pool, the laminated portion (lc) may be formed. At this time, by preheating the base portion 1a by the preheating control unit 400 to be described later, the cooling rate and the solidification rate of the laminated portion 1c can be lowered, thereby preventing the occurrence of heat shrinkage.

Meanwhile, the laser unit 320 may inject a process gas along the laser flow path 322 so that a process gas is injected around the laser beam 321 to be irradiated together with the laser beam 321. It is possible to prevent oxidation of the molten pool melted by the laser beam 321 by the process gas. In order to smoothly irradiate the laser beam 321, an optical means for irradiating the laser beam 321, a coaxial gas portion for injecting a process gas, etc. may be further included, but this is a known technique and a detailed description thereof is omitted here. Do it.

The shielding gas part 330 is a shielding gas 331 for preventing oxidation of the metal powder material 311 of the punch mold 1 and the laminated part lc due to heat generated by the laser beam 321. ) To supply. To this end, a shielding gas flow path 332 is formed inside the nozzle frame 301, and the shielding gas 331 may be supplied through the shielding gas flow path 332. That is, the shielding gas flow path 332 is preferably formed in the inside of the nozzle frame 301 to the outside of the powder flow path 312 and spaced apart from the powder flow path 312, and the shielding gas 331 It may move from one side of the nozzle frame 301 to the other side along the shielding gas flow path 332 and be sprayed to the outside of the stacking part lc. That is, the shielding gas 331 is discharged to the other side of the nozzle frame 301, so that the shielding gas () to the outside of the punch mold 1 and the stacking part lc melted by the laser beam 321 Since 331) can be supplied continuously, oxidation can be prevented by shielding the melting part from the outside. The shielding gas 331 is an inert gas or a translucent gas, preferably an argon gas (Ar), a helium (He) mixed gas, etc., and a shielding gas frame for accommodating the shielding gas 331 may be further provided, This is a known technique and a detailed description thereof will be omitted here.

The preheating control unit 400 is for preheating the punch mold 1 using the 3D printer unit 300, and the base unit 1a before laminating the metal powder material 311 in the 3D printer unit 300 ) To prevent heat shrinkage when forming the stacked portion 1c in the 3D printer unit 300, thereby improving stackability. The preheat control unit 400 controls the laser beam 321 of the 3D printer unit 300 to preheat the punch mold 1 before laminating the metal material in the 3D printer unit 300. That is, the preheating control unit 400 may be connected to the laser unit 320 to control the laser beam 321. The preheating control unit 400 may include a preheating unit 410 and a temperature sensing sensor 420.

The preheating line unit 410 is for selecting a preheating condition for preheating the punch mold 1, and may select a preheating condition corresponding to the stacking portion 1c to be stacked on the punch mold 1. In addition, the preheating line part 410 may select a preheating time, preheating temperature, preheating holding time, etc. for preheating the base part 1a, and formed on the punch mold 1 and the punch mold 1 A preheating time, a preheating temperature, a preheating maintenance time, etc. are selected according to the size and shape of the stacked portion (lc) to be formed.

The temperature sensor 420 detects the temperature of the punch mold 1. That is, the temperature sensor 420 is provided on one side of the punch mold 1 to detect the temperature of the punch mold 1 to be preheated by the preheating control unit 400, and the temperature sensor 420 By sensing the temperature of the punch mold 1, the preheating control of the punch mold 1 can be automatically controlled in response to the preheating condition selected by the preheating unit 410, thereby improving efficiency.

Meanwhile, the preheating control unit 400 preheats the base unit 1a by controlling the wavelength of the laser beam 321 of the 3D printer unit 300, and the preheating condition selected by the preheating unit 410 and the The punch mold 1 may be preheated by controlling the wavelength of the laser beam 321 of the 3D printer unit 300 in response to the temperature of the punch mold 1 sensed by the temperature sensor 420. That is, the preheating control unit 400 controls the wavelength of the laser beam 321 to correspond to a preheating time, a preheating temperature, and a preheating maintenance time for preheating the base unit 1a selected by the preheating line unit 410. Thus, it is possible to appropriately preheat the punch mold (l). In addition, the preheating control unit 400 is connected to the temperature sensing sensor 420, and the temperature sensing sensor 420 continuously senses the temperature of the punch mold 1 to be selected by the preheating selection unit 410 It is possible to appropriately control the wavelength of the laser beam 321 according to the preheating time, preheating temperature, and preheating maintenance time. By preheating the base part 1a by the preheating control part 400, the stackability of the punch mold 1 is improved, and a high-speed tool steel powder material or high-strength cold-rolled tool steel having a strength greater than that of the base part 1a Even if the powdered metal powder material 311 is laminated, it is possible to improve manufacturing efficiency by preventing defects such as cracks from occurring between the base portion la and the laminated portion lc.

On the other hand, Figures 6 to 8 are flow charts showing a punch mold high-strength material lamination method (S10) according to the third embodiment of the present invention. The punch mold high-strength material lamination method (S10) relates to a method for manufacturing a punch mold 1 for shearing, such as piercing or trimming, a part whose strength is reinforced by a hot stamping process, and the punch mold The punch mold 1 can be manufactured using the high-strength material lamination apparatus 10 and 20. Here, the same reference numerals for the punch mold 1 and the punch mold high-strength material laminating apparatus 10 are the same members having the same configuration and function, so a repetitive description will be omitted. The punch mold high strength material lamination method (S10) may include a lamination pretreatment step (S100), a punch mold preheating step (S200), and a 3D printing lamination step (S300).

The pre-lamination step (S100) is to determine the range, shape and material of the laminated portion (1c) of the metal material to be laminated on the punch mold (1), the punch mold stress analysis step (S110), the lamination range It may include a selection step (S120), the stacked shape forming step (S130).

In the punch mold stress analysis step (S110), the stress distribution of the punch mold 1 is analyzed. That is, in the punch mold stress analysis step (S110), the stress distribution is analyzed by analyzing the strength generated in the punch mold 1 manufactured according to the purpose. The stress distribution of the punch mold 1 analyzed in the punch mold stress analysis step (S110) generates a predictive simulation for factors such as the work material forming the punch mold 1, the punch speed, and the gap between the punch and the die. Can be analyzed. In addition, in the punch mold stress analysis step (S110), the analysis of the stress distribution of the punch mold 1 includes the critical damage value of the work material forming the punch mold 1, the number of simulated fracture elements, finite element mesh optimization conditions, etc. Analysis can be included.

The stacking range selection step (S120) is to determine the range of the stacked portion (1c) of the metal material to be stacked on the punch mold (1), the punch mold (1) analyzed in the punch mold stress analysis step (S110). In response to the stress distribution of ), the range of the laminated portion 1c of the metal material to be laminated on the punch mold 1 can be determined. That is, the width, depth and shape of the stress distribution of the punch mold 1 corresponding to the stress distribution of the punch mold 1 analyzed in the punch mold stress analysis step (S110) are analyzed, and the punch It is possible to select a range of the laminated portion 1c to improve the strength of the mold 1.

The stacked shape forming step (S130) is for forming the shape of the stacked portion 1c to be stacked on the punch mold 1, and the range of the stacked portion 1c selected in the stacking range selection step S120 Corresponding to that, the shape of the lamination portion 1c to be laminated on the punch mold 1 may be formed. That is, in the stacked shape forming step (S130), the shape of the stacked portion (1c) to be stacked is designed to correspond to the stacking range to improve the strength of the punch mold (1) selected in the stacking range selection step (S120). In other words, the step of forming the layered shape (S130) may further include the step of analyzing the strength of the layered portion.

In the layered portion strength analysis step, the strength of the layered portion 1c formed in the layered shape forming step (S130) is analyzed and analyzed. In other words, by analyzing the strength of the laminated part 1c and the structural bonding strength of the interface between the base part 1a and the laminated part 1c through the strength analysis step of the laminated part, the punch mold 1 is requested. It is possible to form a final shape of the laminated part 1c by checking whether the strength is suitable for the laminated part 1 to be formed.

The punch mold preheating step (S200) is for preheating the punch mold 1 in which the lamination portion 1c is to be laminated, and heat is applied to the punch mold 1. That is, in the punch mold preheating step (S200), the base portion 1a is preheated before the stacking portion 1c determined in the stacking pretreatment step S100 is stacked. The punch mold preheating step (S200) may preheat the punch mold 1 by using induction heating or control the wavelength of the laser beam 321 to preheat the punch mold 1, and the punch mold ( It is preferable to preheat 1) to 200 degrees or more. By preheating the base portion 1a by the punch mold preheating step (S200), the cooling rate and the solidification rate of the laminated portion 1c may be lowered, thereby preventing heat shrinkage from occurring. That is, by preheating the base portion 1a by the punch mold preheating step (S200), the lamination of the punch mold 1 is improved, and the base portion in the 3D printing lamination step (S300) to be described later Even if a high-speed tool steel powder material having a strength greater than the strength of (1a) or a metal powder material 311 of high-strength cold-rolled tool steel powder is laminated, defects such as cracks are formed between the base portion (la) and the stacking portion (lc). It is possible to improve manufacturing efficiency by preventing it from occurring. The punch mold preheating step (S200) may include the preheating temperature control step (S210) and the preheating speed control step (S220).

In the preheating temperature control step S210, a preheating temperature for preheating the punch mold 1 is controlled. That is, the preheating temperature control step S210 may control a preheating temperature for preheating the punch mold 1 in response to the material and shape of the punch mold 1 and the material and shape of the stacking part lc. .

In the preheating speed control step (S220), the speed of preheating the punch mold 1 is controlled. That is, in the preheating speed control step (S220), a preheating time for preheating the punch mold 1 and a preheating maintenance time corresponding to the material and shape of the punch mold 1 and the material and shape of the stacking part lc are determined. Control to control the preheating speed.

The 3D printing lamination step (S300) is a step of laminating a lamination portion (lc) on the base portion (1a), supplying a metal powder material 311 to the punch mold (1), and irradiating a laser beam (321) Thus, the punch mold 1 and the metal powder material 311 are directly melted to laminate the metal material. The 3D printing lamination step (S300) uses a 3D printing technology using a Directed Energy Deposition (DED) method. In the 3D printing lamination step (S300), the base portion (la) by stacking a lamination portion (1c) on the punch mold (1) in response to the shape of the lamination portion (1c) determined in the lamination pre-processing step (S100). It is possible to form a processed portion (1b) having a strength greater than the strength of. In other words, the metal powder material 311 supplied in the 3D printing lamination step (S300) is a high-strength metal powder material 311 having a strength greater than that of the base portion 1a of the punch mold 1, molybdenum ( Mo), tungsten (W), vanadium (V) is preferably a high-speed tool steel powder material or high-strength cold-rolled tool steel powder containing alloying elements such as. Accordingly, in the 3D printing lamination step (S300), the metal powder material 311 of high strength is supplied, and a laser beam 321 is irradiated at a position corresponding to the supplied metal powder material 311 to be applied to the punch mold (1). ) And the metal powder material 311 may be directly melted to laminate the metal material on the base portion la to enhance strength. In the 3D printing lamination step (S300), manufacturing efficiency may be increased by forming the lamination portion 1c having a suitable shape in response to the stress distribution of the punch mold 1 through the lamination pretreatment step S100.

Meanwhile, in the 3D printing lamination step (S300), a metal powder material 311 of a high-strength functional material is supplied to the base portion 1a, so that the lamination portion 1c can be laminated to be composed of a first layer layer having high-strength functionality. In addition, after forming a first layer layer having impact resistance by supplying a metal powder material 311 of an impact resistant material to the base portion 1a, metal powder of a high strength functional material on the first layer layer having impact resistance By supplying the material 311 to form a second layer layer having high strength functionality, the laminated portion 1c may be laminated such that it is composed of a first layer layer and a second layer layer having high strength functionality and impact resistance. . In addition, in the 3D printing lamination step (S300), in order to manufacture the punch mold 1 that requires high strength and high toughness, it is possible to laminate to have three layers. More specifically, the first layer layer is made of the tool steel material (SKD11) of the general punch mold (1) as the base portion (1a), and the second layer layer is laminated with high toughness material powders (P21, H13) to provide high toughness. The third layer layer may be applied to impart high strength by laminating high-strength material powder such as high wear-resistant tool steel (HWS) or high-speed tool steel (M2, M4). That is, in the 3D printing lamination step (S300), a customized punch mold 1 having the required strength may be obtained by partially controlling and laminating a portion requiring strength on the punch mold 1.

According to the apparatus and method for laminating a high-strength material for a punch mold according to the present invention, a processing portion having a strength greater than that of the base portion is formed in the punch mold, so that a post-treatment process of a component whose strength is reinforced by a hot stamping process is possible. Accordingly, damage and damage to the punch mold can be prevented and the efficiency of use can be improved.

In addition, by preheating the punch mold before laminating the metal powder material using the preheating unit, the cooling rate and the solidification rate are controlled to prevent lamination defects, thereby improving lamination.

In addition, by partially laminating the metal powder material for forming the processing part on the punch mold using the 3D printer, the mechanical properties of the punch mold are improved and the manufacturing efficiency is high. By forming the laminated portion, manufacturing efficiency can be increased.

The present invention has been described with reference to the embodiments shown in the drawings, but these are merely exemplary, and those of ordinary skill in the art will appreciate that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

1: punch mold 1a: base
1b: processed part 1c: laminated part
10, 20: punch mold high strength material lamination device 100: fixed frame
200a,200b: preheating unit 210: induction heater
220: heater insulation 230: auxiliary induction heater
240: heating control unit 250: induction heating coil
260: coil control unit 270,420: temperature sensor
300: 3D printer unit 301: nozzle frame
310: powder supply unit 311: metal powder material
312: powder flow 313: powder frame
320: laser unit 321: laser beam
322: laser flow path 330: shielding gas part
331: shielding gas 332: shielding gas flow path
400: preheating control unit 410: preheating unit

Claims (13)

In the punch mold high strength material lamination apparatus for manufacturing a punch mold having a base portion and a processing portion having a strength greater than the strength of the base portion formed on one side of the base portion,
A fixed frame in which the punch mold is fixedly disposed on the upper surface;
An induction heating coil provided on one side of the fixed frame to preheat the punch mold disposed on the fixed frame, and disposed in a cylindrical shape along the outer circumference of the punch mold to apply heat to the punch mold, and the induction heating coil Preheating unit including a coil control unit for controlling the; And
Includes a 3D printer unit provided to be movable on one side of the fixed frame, supplying a metal powder material to the punch mold, and laminating the metal material by directly melting the punch mold and the metal powder material by irradiating a laser beam High-strength material lamination device for punching molds. The method according to claim 1,
The preheating unit,
An induction heater disposed on one side of the punch mold to apply heat to the punch mold to heat treatment,
A heater insulating material provided along the outer circumference of the induction heater,
An auxiliary induction heater disposed on the other side of the punch mold to auxiliaryly apply heat to the punch mold,
A punch mold high strength material lamination apparatus comprising a heating control unit for controlling the induction heater and the auxiliary induction heater. delete The method according to claim 1,
The 3D printer unit,
A nozzle frame provided to be movable on one side of the fixed frame,
A powder supply unit that has a powder flow path formed inside the nozzle frame to supply a metal powder material to the punch mold,
A laser unit for directly melting the metal powder material supplied from the punch mold and the powder supply unit by irradiating a laser beam by forming a laser flow path inside the nozzle frame,
A punch mold high strength material lamination apparatus comprising a shielding gas section having a shielding gas flow path formed inside the nozzle frame to supply shielding gas to the shielding gas flow path to shield a part melted from the laser section from the outside. In the punch mold high strength material lamination apparatus for manufacturing a punch mold having a base portion and a processing portion having a strength greater than the strength of the base portion formed on one side of the base portion,
A fixed frame in which the punch mold is fixedly disposed on the upper surface;
A 3D printer unit provided to be movable on one side of the fixed frame, supplying a metal powder material to the punch mold, and laminating the metal material by directly melting the punch mold and the metal powder material by irradiating a laser beam; And
Preheating the punch mold before laminating the metal material in the 3D printer unit by controlling the laser beam of the 3D printer unit, a preheating unit for selecting a preheating condition of the punch mold, and temperature sensing for sensing the temperature of the punch mold Punch mold high strength material lamination device comprising a preheating control unit including a sensor. The method of claim 5,
The 3D printer unit,
A nozzle frame provided to be movable on one side of the fixed frame,
A powder supply unit that has a powder flow path formed inside the nozzle frame to supply a metal powder material to the punch mold,
A laser unit for directly melting the metal powder material supplied from the punch mold and the powder supply unit by irradiating a laser beam by forming a laser flow path inside the nozzle frame,
A punch mold high strength material lamination apparatus comprising a shielding gas section having a shielding gas flow path formed inside the nozzle frame to supply shielding gas to the shielding gas flow path to shield a part melted from the laser section from the outside. delete The method of claim 5,
The preheating control unit,
A punch mold high strength material lamination apparatus for preheating the punch mold by controlling the wavelength of the laser beam of the 3D printer unit in response to the preheating condition selected by the preheating unit and the temperature of the punch mold detected by the temperature sensor. In the punch mold high strength material lamination method for manufacturing a punch mold having a base portion and a processing portion having a strength greater than the strength of the base portion formed on one side of the base portion,
A lamination pre-treatment step of determining a range, shape, and material of the lamination portion of the metal material to be laminated on the punch mold;
A punch mold preheating step of preheating a punch mold for stacking the stacked portions determined in the stacking pretreatment step; And
3D printing lamination in which a metal powder material is supplied to the punch mold in response to the shape of the laminate determined in the pre-lamination step, and the metal material is laminated by directly melting the punch mold and the metal powder material by irradiating a laser beam. Punch mold high-strength material lamination method comprising the step. The method of claim 9,
The lamination pretreatment step,
A punch mold stress analysis step to analyze the stress distribution of the punch mold,
In response to the stress distribution of the punch mold analyzed in the punch mold stress analysis step, a lamination range selection step of determining a range of the lamination portion of the metal material to be laminated on the punch mold,
A method of laminating a punch mold high-strength material comprising a lamination shape forming step of forming a shape of a lamination portion to be laminated to the punch mold in correspondence with the lamination range selected in the lamination range selection step. The method of claim 9,
The punch mold preheating step,
Punch mold high strength material lamination method for preheating the punch mold using induction heating. The method of claim 9,
The punch mold preheating step,
A preheating temperature control step of controlling a temperature for preheating the punch mold,
Punch mold high strength material lamination method comprising a preheating speed control step of controlling a speed of preheating the punch mold. The method of claim 12,
The punch mold preheating step,
Punch mold high strength material lamination method for preheating the punch mold to 200 degrees or more.

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