KR101516402B1 - Pre-heating device for bending press - Google Patents

Abstract

A preheating device for a bending press is disclosed. According to an embodiment of the present invention, the preheating device for a bending press includes: an upper heating unit installed in a front end of a robot arm installed in one side of a bending press and formed to be moved, preheating an upper portion of a bumper beam during clamping of the bumper beam and inputting the bumper beam into the bending press by an operation of a robot; a lower heating unit positioned inside the movement range of the robot in a working site where the clamped bumper beam is mounted through the upper heating unit, and preheating a lower portion of the bumper beam; and a power controller supplying power to the upper heating unit and the lower heating unit.

Description

[0001] PRE-HEATING DEVICE FOR BENDING PRESS [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a preheating apparatus for a bending press, and more particularly, to a preheating apparatus for a bending press capable of press-molding a bumper beam of aluminum or a magnesium alloy material produced through extrusion molding in a warm state.

Generally, the aluminum bumper beam is manufactured through extrusion molding. The aluminum bumper beam is manufactured by applying a method such as stretch bending, roll bending, and press bending to form an extruded cross-section with a certain curvature to be applied to a vehicle.

The stretch bending is a technique in which both ends of the metal pipe to be permanently deformed are fixed and the bending is performed by changing the angles of both ends of the metal pipe with the oil pressure. In the roll bending, The press bending is a technique of attaching the tube to a stretch bending machine, and then tensioning both ends of the bumper beam and bending molding.

However, the stretch bending has a disadvantage in that productivity is low due to a long cycle time due to a large number of processes including the step of putting the material into the product and taking it out to the product, and the roll bending is not subjected to tensile molding to the permanent strain point of the plastic deformation of the material There is a disadvantage that the curvature quality due to springback can not be guaranteed.

In order to solve these drawbacks, press bending method has been applied recently. However, in the case of press bending, the cycle time can be reduced compared to stretch bending. However, since the fixing method is somewhat unstable and the dimensional accuracy is somewhat lower than that of stretch bending, There is a problem that additional foaming stamping molding that requires a second or third order is required depending on the shape.

Further, after the bumper beam produced by the extrusion molding is preheated by a local heating method using a high frequency heater and then transferred to the bending press, heat loss is generated in the bumper beam, the thermal efficiency is lowered, There is also a problem.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a bumper beam of aluminum or magnesium alloy which is manufactured through extrusion and supplied to a bending press, The bumper beam can be formed by pressing the bumper beam to a predetermined position, and the bumper beam can be formed at the same time as the bumper beam, And to provide a preheating device.

In order to accomplish the above object, a preheating apparatus for a bending press according to an embodiment of the present invention is mounted on a front end of an arm of a robot provided at one side of a bending press and is movable so that the bumper beam is clamped, An upper heating unit for preheating an upper portion of the bumper beam and for injecting the bumper beam into the bending press by operation of the robot; A lower heating unit which is located in a moving range of the robot in a work place, in which the bumper beam clamped through the upper heating unit is seated, and preheats the lower part of the bumper beam; And a power controller for supplying power to the upper heating unit and the lower heating unit.

The upper heating unit includes a clamper mounted on an arm end of the robot and clamping both sides in the width direction of the bumper beam; And an upper heater mounted on the inner side of the clamper to heat the upper surface of the bumper beam.

The upper heater may have at least one or more along the longitudinal direction at an inner center of the clamper.

The upper heater may be mounted adjacent to an upper surface of the bumper beam inside the clamper.

The upper heater may be constituted by a high frequency heater.

The upper heater may be configured as an infrared lamp.

The lower heating unit includes a base frame installed at the floor of the workplace; A fixed die mounted on the base frame, the fixed die on which the bumper beam is seated and fixed; And at least one lower heater disposed on both sides of the fixing frame at the upper portion of the base frame and at a lower portion of the fixing die to preheat the lower and both sides of the bumper beam.

The fixing die may be mounted on both sides of the base frame corresponding to the width direction of the bumper beam, respectively.

The lower heater may be mounted on both sides of each of the fixing dies and at least one along the longitudinal direction at the center of the upper surface of the base frame between the fixing die and the fixing die.

The lower heater may be installed adjacent to both side surfaces and the lower surface of the bumper beam on the upper portion of the base frame.

The lower heater may be constituted by a high-frequency heater.

The lower heater may be constituted by an infrared lamp.

As described above, according to the preheating apparatus for a bending press according to the embodiment of the present invention, the bumper beam of the aluminum or magnesium alloy material produced through the extrusion molding and supplied to the bending press is press- So that the moldability of the material can be improved at the time of press molding.

Further, since a bumper beam made of aluminum or a magnesium alloy excellent in thermal conductivity and high-temperature moldability is formed in a warm-formed state within a set temperature range, the molding quality of the product is improved and bending and foaming are simultaneously performed There is also an effect of reducing the cycle time and improving the productivity while reducing the cost.

1 is a front view of a preheating apparatus for a bending press according to an embodiment of the present invention.
2 is a side view of a preheating device for a bending press according to an embodiment of the present invention.
3 is a plan view of a lower heating unit applied to a preheating apparatus for a bending press according to an embodiment of the present invention.

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

It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory only and are not restrictive of the invention, It should be understood that various equivalents and modifications may be present.

In order to clearly illustrate the present invention, parts not related to the description are omitted, and the same or similar components are denoted by the same reference numerals throughout the specification.

It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory and are intended to provide further explanation of the invention as claimed.

And throughout the specification, when an element is referred to as " comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise.

It should be noted that terms such as " ... unit ", " unit of means ", " part of item ", " absence of member ", and the like denote a unit of a comprehensive constitution having at least one function or operation it means.

2 is a side view of a preheating apparatus for a bending press according to an embodiment of the present invention. FIG. 3 is a cross-sectional view of a bending press according to an embodiment of the present invention. And is a plan view of a lower heating unit applied to a preheating device for press.

Referring to the drawings, a preheating apparatus 100 for a bending press according to an embodiment of the present invention includes a bumper beam B made of an aluminum or magnesium alloy material, which is manufactured through extrusion molding and supplied to a bending press 1, The moldability of the bumper beam B is improved by preheating the bumper beam B until the bumper beam B is put into the bending press 1 so that the bumper beam 1 is formed and the bending and forming are performed simultaneously with the bending press 1, While reducing cycle time and improving productivity.

To this end, the preheating apparatus 100 for a bending press according to an embodiment of the present invention includes an upper heating unit 110, a lower heating unit 120, and a power controller 130 as shown in FIG. .

The upper heating unit 110 is mounted on the tip of the arm 5 of the robot 3 provided at one side of the bending press 1 and is movable so that the bumper beam B is clamped, The upper part of the bumper beam B is preheated and the bumper beam B is introduced into the bending press 1 by the action of the robot 3. [

The behavior of the robot 3 is controlled by a robot controller C provided at one side of the robot 3 and a range of motion of the robot 3 is controlled by a bending press 1 having a top mold 10 and a bottom mold 20 Can be set within a range in which the bumper beam B clamped through the upper heating unit 110 can be placed on the lower mold 20. [

In the present embodiment, the upper heating unit 110 includes a clamper 111 and an upper heater 113, as shown in Figs.

First, the clamper 111 is mounted on the tip of the arm 5 of the robot 3 and clamps both sides of the bumper beam B in the width direction.

The clamper 111 clamps both sides of the bumper beam B in the width direction of the bumper beam B along the longitudinal direction of the bumper beam B to stably clamp the bumper beam B, , So that it is prevented from being separated.

The clamper 111 minimizes external exposure of the heated bumper beam B when the upper portion of the bumper beam B is heated through the upper heater 113, It is possible to prevent heat loss that may occur.

In the present embodiment, the upper heater 113 is mounted inside the clamper 111 to heat the upper surface of the bumper beam B.

The upper heater 113 may be provided with at least one or more along the longitudinal direction in the center of the inside of the clamper 111. In this embodiment, the center of the bumper beam B, which requires curvature molding, One at a position corresponding to both end portions requiring molding, and three in total.

The upper heater 113 may be mounted adjacent to the upper surface of the bumper beam B on the inner side of the clamper 111.

Here, the upper heater 113 may be constituted by a high-frequency heater, or may be constituted by an infrared lamp.

In the preheating device 100 for bending press according to the embodiment of the present invention, the upper heater 113 is mounted at a position corresponding to the center and both ends of the bumper beam B, The number and position of the upper heater 113 may be changed according to the length and shape of the bumper beam B. [

The lower heating unit 120 is located in a moving range of the robot 3 in the workplace and the bumper beam B clamped through the upper heating unit 110 is seated, And the lower part of the heat exchanger is preheated.

The lower heating unit 120 includes a base frame 121, a fixing die 123, and a lower heater 125, as shown in FIG.

First, the base frame 121 is installed on the floor of the workplace within the range of the motion of the robot 3. [

The fixing die 123 is mounted on the upper portion of the base frame 121, and the bumper beam B is seated and fixed.

The fixing die 123 is mounted on both sides of the upper part of the base frame 121 corresponding to the width direction of the bumper beam B and clamped to the clamper 111 of the upper heating unit 110. [ The lower surface of the bumper beam B which is moved downward and supported is reliably supported and seated.

The lower heater 125 is installed on both sides of the base frame 121 with the fixing die 123 interposed therebetween and below the fixing die 123 so that the bumper beam B And the lower and both sides are preheated.

At least one of the lower heater 125 may be mounted along the longitudinal direction at the center of the upper surface of the base frame 121 between both sides of the fixing die 123 and the fixing die 123.

Here, the lower heater 125 is provided at the center corresponding to the above-described upper heater 113, at which the curvature molding of the bumper beam B is required, and at the positions corresponding to both end portions required to be bent, Three sets of one pair of the bumper beams B are provided on both sides in the width direction and the bottom center of the bumper beam B.

The lower heater 125 may be installed adjacent to both the upper and lower surfaces of the bumper beam B on the upper portion of the base frame 121.

Here, in the preheating apparatus 100 for a bending press according to the embodiment of the present invention, the lower heater 125 is disposed at a position corresponding to both the bottom center and the widthwise side in the longitudinal direction of the bumper beam B, However, the number and position of the lower heater 113 are not limited to the length and shape of the bumper beam B, Can be changed and applied.

The lower heater 125 may be constituted by a high-frequency heater, and an infrared lamp may also be configured as a heat source.

The high frequency heater, which can be applied to the upper heater 113 and the lower heater 125 in the bending press preheating apparatus 100 according to the present embodiment, is heated using a frequency of a current set higher than the frequency distributed to the broadcasting network The heating temperature of the filament of the lamp is appropriately adjusted in a lamp which heats the infrared ray of the infrared ray and causes the electric current to flow in the ash, Heater.

Such a high-frequency heater and an infrared lamp heater correspond to well-known technologies, and therefore, a description of the configuration will be omitted below.

The power controller 130 is installed in the workplace and selectively supplies power to the upper and lower heaters 113 and 125 of the upper heating unit 110 and the lower heating unit 120 to generate heat.

That is, the bumper press preheater 100 configured as described above moves the upper heating unit 110 to the bumper beam B when the bumper beam B having been subjected to the extrusion molding is transferred, The upper and lower sides of the bumper beam B in the width direction are clamped by the clamper 111 and moved to the fixing die 123 from above the base frame 121 of the lower heating unit 120 .

When the lower surface of the bumper beam B is seated on the fixed die 123, the robot 3 stops moving and the upper and lower heaters 113 and 125 supplied with power from the power supply 130 generate heat The center and both ends of the bumper beam B on both the upper and lower surfaces and both longitudinal sides thereof are intensively heated and preheated.

When the preheating of the bumper beam B is completed after a predetermined time has elapsed in this state, the robot 3 is operated by the robot controller C to place the bumper beam B on the upper portion of the lower mold 20 , The clamping is released and the upper heating unit 110 is returned to the initial position.

The upper heating unit 110 moves the upper surface of the bumper beam B clamped by the clamper 111 through the upper heater 113 while moving the bumper beam B, The heat loss of the heated bumper beam B can be minimized.

Therefore, when the preheating apparatus 100 for a bending press according to the embodiment of the present invention as described above is applied, a bumper beam B made of aluminum or a magnesium alloy material produced through extrusion molding and supplied to a bending press It is possible to improve the formability of the material at the time of press forming by preheating the bending press 100 until the bumper beam B is just before the bumper beam B is injected so that the molding is performed in the warm state.

Further, since the bumper beam B made of an aluminum or magnesium alloy excellent in thermal conductivity and high-temperature moldability is molded in the warm-forming state within the set temperature range, the molding quality of the product is improved and bending and forming Simultaneous execution can reduce costs, while reducing cycle time and improving productivity.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It will be understood that various modifications and changes may be made without departing from the scope of the appended claims.

100: Preheating device
110: upper heating unit
111: clamper
113: Top heater
120: Lower heating unit
121: Base frame
123: Fixed die
125: Lower heater
B: Bumper beam

Claims (12)

The bumper beam is mounted on the arm tip of the robot provided at one side of the bending press and is movable so as to preheat the upper part of the bumper beam in a state of clamping the bumper beam, An upper heating unit for heating the upper heating unit;
A lower heating unit which is located in a moving range of the robot in a work place, in which the bumper beam clamped through the upper heating unit is seated, and preheats the lower part of the bumper beam; And
A power controller for supplying power to the upper heating unit and the lower heating unit;
And a preheating device for the bending press. The method according to claim 1,
The upper heating unit
A clamper mounted on an arm end of the robot and clamping both sides in the width direction of the bumper beam; And
An upper heater mounted on the inner side of the clamper to heat the upper surface of the bumper beam;
And a preheating device for the bending press. 3. The method of claim 2,
The upper heater
Wherein at least one of the at least one bending press is provided along the longitudinal direction at an inner center of the clamper. 3. The method of claim 2,
The upper heater
Wherein the bumper beam is mounted adjacent to an upper surface of the bumper beam from the inside of the clamper. 3. The method of claim 2,
The upper heater
And a high-frequency heater. 3. The method of claim 2,
The upper heater
Characterized in that the infrared lamp is constituted by heat. The method according to claim 1,
The lower heating unit
A base frame installed on the floor of the workplace;
A fixed die mounted on the base frame, the fixed die on which the bumper beam is seated and fixed; And
At least one lower heater installed on both sides of the base frame above the stationary die and under the stationary die to preheat the lower and both sides of the bumper beam;
And a preheating device for the bending press. 8. The method of claim 7,
The fixed die
Wherein the bumper beam is mounted on both sides of the base frame corresponding to the width direction of the bumper beam. 9. The method of claim 8,
The lower heater
Wherein at least one of the fixing die and the stationary die is mounted along the longitudinal direction at the center of the upper surface of the base frame between both sides of the fixing die and the fixing die. 8. The method of claim 7,
The lower heater
Wherein the bumper beam is installed adjacent to the upper and lower surfaces of the bumper beam at the upper portion of the base frame. 8. The method of claim 7,
The lower heater
And a high-frequency heater. 8. The method of claim 7,
The lower heater
Characterized in that the infrared lamp is constituted by heat.

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