KR20130023711A - Flame machineing simulator - Google Patents

Abstract

PURPOSE: A hot-rolled flame processing simulation device is provided to accurately determine changes in properties of a material by a hot-rolled flame processing and to obtain an optimal condition of the hot-rolled flame processing. CONSTITUTION: A hot-rolled flame processing simulation device(100) comprises a bed unit(110), a support arm unit(120), an x-axis driving unit(125), a rail unit(122), a head unit(130), a y-axis driving unit(135), a heating torch unit(140), a z-axis driving unit(145), a cooling nozzle unit(150), and a controller. A specimen(10) is arranged on the bed unit. The support arm unit is formed in the bed unit to be slid in an x-axis direction. The x-axis driving unit regulates an x-axis transferring speed of the support arm unit. The rail unit is connected to the support arm unit. The head unit is formed in the rail unit to be slid in a y-axis direction. The y axis driving unit regulates a y-axis transferring speed of the head unit.

Description

Hot flame simulation device {FLAME MACHINEING SIMULATOR}

The present invention relates to a hot flame simulation apparatus which is a processing method for creating a curved surface of a heavy plate, and more particularly, to a hot flame simulation apparatus which enables hot flame processing under various conditions on a specimen.

Hot flame processing is a method used in the processing of curved surface of the bow, stern, etc. of the ship, it is made by locally heating the raw material using a heat source and then cooling the local heating unit.

When the plate is locally heated, the local heating unit expands, and when the local heating unit cools, the part is contracted again. However, due to such local heating and shrinkage, the difference in shrinkage in the thickness direction occurs, thereby bending processing is performed.

Related prior arts include Korean Patent Publication No. 2011-0046652 (published May 6, 2011).

SUMMARY OF THE INVENTION An object of the present invention is to provide a hot flame processing yarn that can hot-flame the specimen under various conditions.

The present invention for achieving the above object is a flat plate-shaped bed section; A support arm slidably formed in the bed portion in an x-axis direction; An x-axis driving unit controlling an x-axis feed speed of the support arm; A rail unit connected to the support arm; A head portion slidably formed in the y-axis direction of the lay portion; A y-axis driving unit controlling the y-axis feed speed of the head unit; A heating torch unit which is formed to be able to move up and down in the z-axis direction; A z-axis driving unit adjusting the z-axis height of the heating torch unit; A cooling nozzle unit in which the horizontal distance with the heating torch unit is adjustable in the head unit; And a control unit for controlling the x-axis driving unit, the y-axis driving unit, and the z-axis driving unit.

Here, the x-axis drive unit, the y-axis drive unit and the z-axis drive unit preferably includes a servo motor so that the speed and position are controlled by the controller.

In addition, the support arm is preferably a pair of vertical portion and the horizontal portion is formed in the '' 'shape so that the head portion can move freely in the three-axis direction from the top of the specimen.

The head unit may further include a sensor unit configured to measure a distance between the head unit and the specimen.

In this case, the sensor unit transmits a distance signal to the controller, and the controller controls the z-axis driving unit to maintain a constant distance between the heating torch unit and the specimen.

The cooling nozzle unit may adjust the cooling rate by allowing the flow rate of the cooling water to be injected.

The controller simulates hot flame processing by controlling the x-axis drive unit and the y-axis drive unit so that the cooling nozzle unit follows the heating torch unit.

The present invention makes it possible to evaluate the material properties by hot flame processing by allowing the material to be hot flame processed under various conditions.

Therefore, it is possible to accurately determine the change of the material properties by hot flame processing, bringing the effect of deriving the optimum hot flame processing conditions.

1 is a perspective view schematically showing a hot flame simulation apparatus according to an embodiment of the present invention,
Figure 2 is a side view schematically showing the heating torch portion and the cooling nozzle portion of the hot flame simulation apparatus according to an embodiment of the present invention.

Advantages and features of the present invention, and methods for achieving them will be apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in various forms, and provided to fully inform the scope of the invention to those skilled in the art. It is intended that the invention be defined only by the scope of the claims. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail.

1 is a perspective view schematically showing a hot flame simulation apparatus according to an embodiment of the present invention.

The hot flame processing simulation apparatus 100 according to the present invention includes a bed portion 110 having a flat plate shape on which the specimen 10 is mounted, and a support arm portion 120 slidably formed at both sides of the bed portion 110. In addition, the x-axis driving unit 125 for adjusting the x-axis feed rate of the support arm 120, the rail unit 122 connected to the support arm 120, and the rail unit 122 in the y-axis direction The head 130 is formed to be slidable, the y-axis driving unit 135 to control the y-axis feed rate of the head 130, and the head 130 is formed to be able to move up and down in the z-axis direction The separation distance between the heating torch unit 140, the z-axis driving unit 145 for adjusting the z-axis height of the heating torch unit 140, and the heating torch unit 140 on the head unit 130 is adjusted. It includes a cooling nozzle unit 150 formed to be possible, and a control unit (not shown) for controlling the x-axis drive unit 125, the y-axis drive unit 135 and the z-axis drive unit 145. .

Specimen 10 is used to prepare a plate of a size that can be seated on the bed 110 to the material to be processed by the hot flame processing method.

The hot flame simulation apparatus 100 according to the present invention locally heats the specimen 10 using the heating torch unit 140 and then locally cools the heated portion using the cooling nozzle unit 150. After the specimen 10 undergoes the same process as during hot flame processing, it is for evaluating the material of the specimen 10.

The hot flame processing simulation apparatus 100 according to the present invention can control the heating torch unit 140 and the cooling nozzle unit 150 in three axial directions, and also the heating torch unit 140 and the cooling nozzle unit 150. By controlling the separation distance between them, it is possible to simulate various hot flame processing process conditions.

The bed 110 is formed to seat and fix the rectangular plate-shaped specimen 10, and has a pair of guides 112 formed on both sides in parallel in the x-axis direction.

The bed part 110 seats the specimen 10 and does not restrain the specimen 10.

When a flame and coolant are applied locally to the specimen 10, the specimen 10 is bent to the same surface as in the case of hot flame processing. Will suffer. Therefore, the bed 110 is mounted so that the specimen does not move, so that the specimen 10 may be bent.

The support arm 120 has two vertical parts 120a and one horizontal part 120b connected to each other to have a substantially C shape, and a lower end thereof is slidably connected to the guide 112 of the bed part 110. Accordingly, the support arm 120 may linearly move in the x-axis direction with respect to the bed 110.

The support arm 120 is provided with an x-axis driver 125, and by controlling the x-axis driver 125, the x-axis moving speed of the support pressure part 120 can be adjusted.

The x-axis drive unit 125 preferably includes a servomotor to control the speed and position of the support arm 120.

The support arm 120 is provided with a rail portion 122 parallel to the horizontal portion and parallel to the y-axis direction of the bed portion 110. The rail part 122 is formed to be spaced apart from the surface of the bed part 110 by a predetermined height.

The head part 130 is slidably connected to the rail part 122, and the heating torch part 140 and the cooling nozzle part 150 are connected to the head part 130 so as to move up and down in the z-axis direction.

The head unit 130 is controlled in the y-axis movement speed by the y-axis drive unit 135.

The y-axis drive unit 135 preferably includes a servomotor to control the speed and position of the head unit 120 in the y-axis direction.

The heating torch unit 140 and the cooling nozzle unit 150 are adjusted in the z-axis direction by the z-axis driving unit 145. The z-axis position of the heating torch unit 140 and the cooling nozzle unit 150 will be described later with reference to FIG. 2.

In addition, the hot flame simulation apparatus 100 according to the present invention includes a control unit (not shown) for controlling the x-axis driving unit 125, the y-axis driving unit 135, and the z-axis driving unit 145. By controlling the driving units 125, 135, and 145 in various ways, the control unit may move the heating torch unit 140 and the cooling nozzle unit 150 at various speeds and paths.

In addition, the control unit controls the x-axis driving unit and the y-axis driving unit so that the cooling nozzle unit 150 follows the heating torch unit 140.

As described above, the hot flame simulation apparatus 100 according to the present invention includes a rail unit 120 movable in the x-axis direction with respect to the bed unit 110, and a y-axis direction with respect to the rail unit 120. The head unit 130 is movable, and the heating torch unit 140 and the cooling nozzle unit 150 are provided to be movable in the z-axis direction with respect to the head unit 130. Mounted specimen 10 can be given a variety of hot flame processing conditions.

Figure 2 is a side view schematically showing a heating torch portion and a cooling nozzle portion of the hot flame simulation apparatus according to an embodiment of the present invention.

As shown, the heating torch unit 140 applies a flame to the surface of the specimen 10 while being spaced apart from the specimen 10 to locally heat the specimen. However, as described above, the specimen 10 may be bent by hot flame processing.

Therefore, in the present invention, it is preferable that the distance H1 between the heating torch unit 140 and the specimen 10 can be kept constant in real time.

To this end, a sensor unit (not shown) capable of measuring the separation distance H1 between the head unit 130 and the specimen 10 is provided, and the controller transmits the distance signal measured by the sensor unit to the controller. The z-axis drive can be adjusted.

In addition, the separation distance H1 between the heating torch unit 140 and the specimen 10 directly affects the amount of heat supplied to the specimen. In other words, the change in the separation distance (H1) brings a change in the supply calories, which affects the maximum heating temperature which is an important variable of the hot flame processing, the present invention controls the maximum heating temperature of the hot flame processing by controlling this can do.

Another important variable in hot flame processing is the cooling start temperature.

The cooling start temperature is directly related to the horizontal distance L between the heating torch unit 140 and the cooling nozzle unit 150. 2 shows an upward direction of the head portion 130, the hot flame simulation apparatus according to the present invention is a trailing portion of the specimen heated by the heating torch 140 in the specimen 10 The cooling nozzle unit 150 is operated to be cooled. Therefore, as the horizontal distance L between the heating torch unit 140 and the cooling nozzle unit 150 becomes longer, the cooling start temperature is lowered, and the horizontal distance between the heating torch unit 140 and the cooling nozzle unit 150 is reduced. The shorter (L), the higher the cooling start temperature.

In addition, it is preferable to control the cooling water flow rate of the cooling nozzle unit 150 in order to control the cooling rate.

Although the embodiments of the present invention have been described above with reference to the accompanying drawings, the present invention is not limited to the above embodiments but may be manufactured in various forms, and having ordinary skill in the art to which the present invention pertains. It will be appreciated that the person may embody other specific forms without changing the technical spirit or essential features of the present nickname. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

100: hot flame simulation apparatus
110: bed section
120: support arm
125: x axis drive part
130: head
135: y-axis drive unit
140: heating torch
145: y-axis drive unit
150: cooling nozzle part
L: horizontal distance

Claims (7)

A bed portion having a flat plate shape for mounting the specimen;
A support arm slidably formed in the bed portion in an x-axis direction;
An x-axis driving unit controlling an x-axis feed speed of the support arm;
A rail unit connected to the support arm;
A head portion slidably formed in the y-axis direction of the lay portion;
A y-axis driving unit controlling the y-axis feed speed of the head unit;
A heating torch unit which is formed to be able to move up and down in the z-axis direction;
A z-axis driving unit adjusting the z-axis height of the heating torch unit;
A cooling nozzle unit in which the horizontal distance with the heating torch unit is adjustable in the head unit; And
And a control unit for controlling the x-axis driving unit, the y-axis driving unit, and the z-axis driving unit.
The method of claim 1,
The x-axis drive unit, the y-axis drive unit and the z-axis drive unit hot flame processing simulation apparatus, characterized in that it comprises a servo motor.
The method of claim 1,
The support arm portion
Hot flame simulation device, characterized in that the pair of vertical portion and the horizontal portion is formed in the '''shape.
The method of claim 1,
Hot flame processing simulation apparatus, characterized in that the head portion further comprises a sensor for measuring the distance between the head and the specimen.
The method of claim 4, wherein
The sensor unit transmits a distance signal to the control unit,
The controller controls the z-axis drive unit to maintain a constant distance between the heating torch unit and the specimen.
The method of claim 1,
The cooling nozzle unit
Hot flame processing simulation apparatus, characterized in that the flow rate of the cooling water is injected.
The method of claim 1,
The control unit
And the x-axis driving unit and the y-axis driving unit so that the cooling nozzle unit follows the heating torch unit.

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