KR20180014274A - Impact test apparatus - Google Patents

Abstract

The present invention provides an impact test apparatus which comprises: a chamber unit in which an internal space is formed; a guide unit installed by penetrating into the chamber unit, wherein a material exposure hole through which a material is exposed is formed; a material insertion unit inserted into the guide unit at the outside of the chamber unit, and provided with at least one material; and a launch unit launching an impact body to the material of the material insertion unit inserted into the guide unit to collide with each other.

Description

[0001] IMPACT TEST APPARATUS [0002]

The present invention relates to an impact test apparatus capable of continuously and rapidly testing a plurality of workpieces.

It should be noted that the contents described in this section merely provide background information on the present invention and do not constitute the prior art.

The material used for the automotive steel sheet is subjected to a shock test for the purpose of qualification and evaluation of the material (S) after surface coating through phosphate treatment and electrodeposition coating.

As shown in FIG. 1, in the impact test, when the electrodeposition coating material is fixed to the fixed plate 20 in the chamber 10, It is an experiment to apply shock to the surface of the material and to maintain the firm adhesion from the impact of stones and other foreign substances in the course of driving.

When the process and structure of the impact test apparatus are viewed, a fixed plate for mounting the material is installed inside the chamber 10 of the square model, and a firing unit 40 is installed facing the material.

The supply hopper 43 and the launching line 41 are connected at right angles to store the impact body M used for the impact test and the air of the pressure set in the air tank 43 through the start button touch is transmitted to the launching line 41 So that the impact body stored in the supply hopper 43 and the launch line 41 is fired and the impact test is performed through the surface collision with the work S.

When one material impact test is completed, the gate of the chamber 10 is opened to remove the inner material, and a new material is assembled to the fixed plate 20, and the impact body M used in the course of the experiment is placed inside the chamber 10 Recycle and reuse.

In the conventional method, since the gate of the chamber is repeatedly opened and closed during the continuous and repetitive impact test using a plurality of workpieces, the workload is excessively increased due to the assembly and separation of the test material and the test time is excessively long There is a problem.

There is a problem that it is difficult to stably assemble and maintain the material by the inflow of the impact body launched through the air supply of the set pressure into the stationary plate 20 and other accessory devices in the chamber 10 and cause facility troubles.

It is difficult to accurately certify and evaluate the quality due to the positional deviation of the workpiece S to be assembled to the fixed plate 20, and there arises a problem in ensuring reproducibility.

There is a problem in that it takes much time to recover the impact body M due to the interference of the fixing plate 20 and peripheral accessories.

Particularly, in the experiment process, the gate of the chamber 10 is repeatedly opened and closed, so that a large amount of non-product and fine dust generated in the process of collision of the impact body (M) Which has a serious effect on respiratory safety.

As one aspect of the present invention, there is provided an impact test apparatus capable of continuously and rapidly testing a plurality of workpieces.

According to an aspect of the present invention, there is provided a plasma processing apparatus comprising: a chamber having an internal space formed therein; A guide part installed to penetrate the chamber part and having a material exposing hole for exposing a workpiece; A material insertion portion inserted into the guide portion from the outside of the chamber portion and provided with at least one material; And a launch unit unit for launching and impacting an impact body on a workpiece of the workpiece insertion unit inserted into the guide unit.

Preferably, the guide portion includes: a guide frame installed through the chamber portion and having a material inserted into an inner space of the chamber portion; And a material exposing hole which is provided at one side of the guide frame and exposes the material to the impact body to be launched by the launching unit.

Preferably, the material inserting portion includes: a plate main body inserted into the guide portion; A material insertion groove formed between adjacent partition members protruding from the plate body and on which a material is seated; And a magnetic body embedded in the plate body to attach a work to the plate body.

Preferably, the material inserting portion includes: a plate main body inserted into the guide portion; An insertion rail installed at both side end regions of the plate body and having a plurality of workpiece assemblies inserted therein; And a support frame installed at a lower end of the insertion rail to support the work assembly.

Preferably, the cover member may further include a cover member installed at the rear of the guide portion to support the impact body moving past at least the guide portion and to guide the impact body to fall downward.

Preferably, the cover member is provided with a curved member provided so as to cover at least the rear of the guide portion, and an installation hole through which the guide portion is inserted is formed.

Preferably, an induction chute provided at a lower portion of the cover member for guiding the impact member falling after collision with the cover member; And a storage container in which the impact body guided by the induction chute drops and is stored.

Preferably, an observation window can be formed in the chamber portion so that a state in which a material to be tested is disposed in the material exposure hole can be formed.

As described above, according to the embodiment of the present invention, it is possible to continuously and quickly test a plurality of workpieces by a simple method without repeatedly opening and closing the impact testing apparatus for replacement of workpieces.

According to an embodiment of the present invention, there is no need to repeatedly open and close an impact test apparatus for replacing a material, and there is no possibility that a non-product and fine dust generated during a collision process are leaked out, It is effective.

1 is a view showing a conventional impact testing apparatus.
2 is a cross-sectional view illustrating an impact test apparatus according to an embodiment of the present invention.
FIG. 3A is a cross-sectional view taken along the line I-I 'of FIG. 2. FIG.
FIG. 3B is a diagram showing a test state according to the impact test apparatus according to an embodiment of the present invention, taken along the line I-I 'of FIG.
4 is a cross-sectional view taken along the line II-II 'of FIG.
5 is a view showing a state in which a material inserting portion is installed in a guide portion of the impact test apparatus of the present invention.
6 is a view showing an embodiment of a material inserting portion of the impact testing apparatus of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. However, the embodiments of the present invention can be modified into various other forms, and the scope of the present invention is not limited to the embodiments described below. Further, the embodiments of the present invention are provided to more fully explain the present invention to those skilled in the art. The shape and size of elements in the drawings may be exaggerated for clarity.

Hereinafter, an impact test apparatus according to an embodiment of the present invention will be described in detail with reference to the drawings.

2, the impact test apparatus according to an embodiment of the present invention includes a chamber unit 100, a guide unit 200, a workpiece insertion unit 300, and a launch unit unit 400, A member 500, an induction chute 600, and a storage can 700.

2, the impact testing apparatus includes a chamber 100 having an inner space formed therein, a material exposing hole 230 through which the material S is exposed and formed through the chamber 100, A material inserting part 300 inserted into the guide part 200 from the outside of the chamber part 100 and provided with at least one workpiece S, And a firing unit unit 400 for firing and impacting the impact body M on the material inserting unit 300 inserted in the fusing unit 300.

As shown in FIGS. 2 and 4, the chamber part 100 may have an internal space, and the chamber part 100 may have a guide part 200 inserted therethrough.

The chamber part 100 is a space in which the impact test of the material S is performed.

3B, the guide part 200 and the material insertion part 300 can be disposed in the inner space of the chamber part 100, and the material insertion part 300 is inserted into the guide part 200 An impact test of the material S can be performed while the impact unit M is continuously fired by the launch unit unit 400 in a state where the impact unit M is continuously fired.

An observation window (not shown) may be formed in the chamber part 100 to allow the material S to be tested to be placed in the material exposure hole 230.

It goes without saying that the observation window (not shown) may be installed at any one side of the chamber 100 as long as the material exposure hole 230 can be easily observed.

However, the observation window may be provided on the front side or the front side of the chamber part 100 to facilitate observation of the material exposure hole 230.

As shown in FIG. 3A, the guide part 200 may be installed through the chamber part 100.

The material inserting portion 300 is inserted into the guide portion 200 provided in the chamber portion 100 and the material inserting portion 300 is inserted into the chamber portion 100 from the outside of the chamber portion 100 Can be installed.

The material S placed on the material inserting portion 300 is exposed to the material exposure hole 230 of the guide portion 200 and the material S is irradiated to the material S by the impact body M emitted by the launching unit 400 The impact test can be carried out continuously with the impact applied.

As shown in FIGS. 2 and 3A, the guide unit 200 may include a guide frame 210 and a material exposure hole 230.

The guide unit 200 includes a guide frame 210 installed to penetrate through the chamber unit 100 and into which the material S is inserted into the inner space of the chamber unit 100, And a material exposure hole 230 which is open at one side and exposes the material S to the impact body M emitted by the launch unit unit 400. [

The guide frame 210 may be formed as a hollow square board in which an inner space is formed, and both sides of the square board may be opened.

The material insertion portion 300 can be inserted into or removed from either side of the opened both side surfaces of the guide frame 210.

A material exposure hole 230 may be formed in the central region of at least the front surface of the guide frame 210.

As shown in FIG. 3A, a material exposure hole 230 may be formed in the front surface and the rear surface of the guide frame 210, respectively.

The material exposure hole 230 may be formed as a rectangular hole, and may be formed through the front and rear surfaces of the central region of the hollow square board-shaped guide frame 210.

The impact unit M can be shot by the launch unit unit 400 in a state where the workpiece S to be tested is disposed in the material exposure hole 230. [

5, the material inserting unit 300 includes a material inserting groove 330 in which a plurality of materials S are accommodated and a material S is fixed in the inserting groove 330 And can be inserted into the guide portion 200.

A plurality of material insertion grooves 330 may be formed in one material inserting portion 300 and a material S may be installed in each of the material inserting grooves 330. In this case, The impact test can be continuously performed on the plurality of workpieces S while the workpiece 200 is moved.

5 (a), the material inserting unit 300 is inserted into the inner space of the guide frame 210 of the guide unit 200, and is spaced apart from the material inserting unit 300 at regular intervals A plurality of material insertion grooves 330 may be formed

A material insertion portion 300 in which a plurality of materials S are integrally installed is inserted into a guide portion 200 and a plurality of materials S are continuously ≪ / RTI >

5B, in a state where the first material S1 provided at the outermost end of the material inserting portion 300 is inserted into the material exposing hole 230 when the material inserting portion 300 is inserted into the guide portion 200, Impact test on the first material (S1) is carried out.

When the impact test for the first material S1 is completed, the second inserting portion 300 is moved inside the guide portion 200 and the second material S2 is disposed in the material exposing hole 230 Impact test for the second material (S2) is carried out.

In this manner, an impact test can be sequentially performed on a plurality of workpieces S provided on the workpiece inserting portion 300.

The material inserting unit 300 can be inserted into the guide unit 200 interchangeably so that a plurality of material inserting units 300 can be replaced with the guide unit 200 to increase the number of the materials S There is an effect that can be continuously tested.

The material inserting unit 300 can be inserted into the guide frame 210 and move the material inserting unit 300 in which the plurality of materials S are installed while inserting the inserting unit 300 into the guide frame 210, S) can be continuously subjected to an impact test.

The launch unit unit 400 moves the impact body M in the direction of the material exposure hole 230 in a state in which the material insertion unit 300 is moved so that the material S to be tested is placed in the material exposure hole 230 The impact test can be carried out while continuously impacting the material (S) by firing.

6 (a), the workpiece inserting unit 300 may include a plate body 310, a workpiece inserting groove 330, and a magnetic body 340.

The material inserting unit 300 is formed between a plate body 310 inserted into the guide unit 200 and an adjacent partition member 320 protruding from the plate body 310, And a magnetic body 340 embedded in the plate body 310 and attaching the workpiece S to the plate body 310. [

The plate body 310 and the partition member 320 constituting the material inserting unit 300 may be made of a PVC material S but the present invention is not limited thereto and various materials S may be applied .

As shown in FIG. 6 (b), the work insert 300 may include a plate body 310, an insert rail 350, and a support frame 360.

The material inserting unit 300 includes a plate body 310 formed to be insertable into the guide unit 200 and a plate member 310 disposed at both side end regions of the plate body 310, An insertion rail 350 into which the assembly T is inserted and a support frame 360 installed at the lower end of the insertion rail 350 to support the work assembly T. [

A plurality of workpieces S may be integrally installed in the workpiece assembly T and the workpiece S may be attached to the workpiece assembly T by embedding the magnetic body 340 in the workpiece assembly T. [

3B, the launch unit unit 400 is a member that collides the impact body M with the material S inserted in the guide unit 200 by collision.

The launching unit 400 includes a launching line 410 to which the impact body M to be injected through the hopper is attached, a feed hopper 430 to supply the impact body M to the launching line 410, And a gas supply unit 450 connected to the emission line 410 to supply a gas for emitting the impact body M at a high pressure.

2 to 4, the impact testing device is installed at the rear of the guide part 200, supports at least the impact body M moving past the guide part 200, The cover member 500 may be formed of a metal plate.

At this time, the guide part 200 and the cover member 500 may be made of stainless steel.

4, the cover member 500 may be formed as a curved member that covers at least a rear portion of the guide unit 200, and an installation hole through which the guide unit 200 is inserted may be formed .

The cover member 500 is formed as a curved member having an arc-shaped cross section and the guide frame 200 of the guide portion 200 is inserted into the mounting hole provided at both side end regions of the curved member, (Not shown).

That is, the guide part 200 may be installed through the chamber part 100 and the cover member 500.

2, the impact test apparatus includes an induction chute 600 provided at a lower portion of the cover member 500 and guiding the impact member M falling down after collision with the cover member 500, And a storage can 700 in which the impact body M induced by the induction chute 600 drops and is stored.

3B, the cover member 500 is provided as a curved member having an arc-shaped cross-section, so that the impact member M collided with the curved cover member 500 bounces in the direction of the curvature center of the curved member And can be guided to the induction chute 600 installed in the central region of the chamber part 100.

3A, the induction chute 600 includes a first induction chute 610 formed to be inclined downward from the inner peripheral surface of the chamber part 100, and a second induction chute 610 connected to the first induction chute 610, And may include an induction chute 630.

The second induction chute 630 has a discharge port 650 at its center and one side of the connection pipe 670 is connected to the lower side of the discharge port 650 and the other side of the connection pipe 670 is connected to the side of the storage can 700 So that the impact body M moving along the first induction chute 610 and the second induction chute 630 can be guided to the storage can 700.

As shown in FIG. 2, a load cell L is installed on the lower side of the storage can 700, so that the weight of the impact body M accommodated in the storage can 700 can be immediately confirmed.

The shock body M stored in the storage cans 700 is supplied to the supply hopper 400 of the launching unit 400 when the load cell L confirms that a certain amount or more of the impact body M is accommodated in the storage can 700, The impact member M can be recycled by performing the impact test again.

Although the embodiments of the present invention have been described in detail, it is to be understood that the scope of the present invention is not limited to the above embodiments and various changes and modifications may be made without departing from the scope of the present invention. It will be obvious to those of ordinary skill in the art.

10: chamber 20: stationary plate
40: launch unit 41: launch line
43: feed hopper 45: air tank
100: chamber part 200: guide part
210: guide frame 230: material exposure hole
300: Material inserting unit 310: Plate main body
320: partition wall member 330: material insertion groove
340: magnetic substance 350: insertion rail
360: support frame 400: launch unit unit
410: launch line 430: feed hopper
450: gas supply part 500: cover member
600: induction chute 610: first induction chute
630: second induction chute 650: outlet
670: Connection piping 700: Storage can
L: Load cell M: Impact body
S: Material S1: First material
S2: second material T: material assembly

Claims (8)

A chamber part having an internal space formed therein;
A guide part installed to penetrate the chamber part and having a material exposing hole for exposing a workpiece;
A material insertion portion inserted into the guide portion from the outside of the chamber portion and provided with at least one material; And
And a launch unit unit for launching and impacting an impact body on the workpiece inserted into the guide unit.
The apparatus according to claim 1,
A guide frame installed to penetrate through the chamber portion and into which a material is inserted into an inner space of the chamber portion; And
And a material exposing hole provided at one side of the guide frame to expose a material to an impact body to be launched by the launching unit.
The apparatus according to claim 1,
A plate body inserted into the guide portion;
A material insertion groove formed between adjacent partition members protruding from the plate body and on which a material is seated; And
And a magnetic body embedded in the plate body to attach a material to the plate body.
The apparatus according to claim 1,
A plate body inserted into the guide portion;
An insertion rail installed at both side end regions of the plate body and having a plurality of workpiece assemblies inserted therein; And
And a support frame installed at a lower end of the insertion rail to support the work assembly.
The method according to claim 1,
And a cover member provided at the rear of the guide portion to support at least an impact body moving past the guide portion and to guide the impact body to fall downward.
6. The apparatus according to claim 5,
And an installation hole formed at a side of the guide portion and configured to cover at least a rear portion of the guide portion, wherein the installation hole is formed through the guide portion.
6. The method of claim 5,
An induction chute provided at a lower portion of the cover member to guide the impact member falling down after colliding with the cover member; And
And a storage can for dropping and storing an impact body guided by the induction chute.
The method according to claim 1,
Wherein an observation window is formed in the chamber part so that a state in which a material to be tested is disposed in the material exposure hole is formed.

Images