KR20190024255A - Sled Impact Test Apparatus - Google Patents

Abstract

The present invention relates to a sled impact test apparatus for impact test of a test body. With the present invention, a rotating plate on which a test body is mounted can be easily mounted on a base plate and rotation angle control for the rotating plate is easily configured. In order to achieve the object, the sled impact test apparatus according to the present invention includes the base plate fixed to a block movable in forward and backward directions, the rotating plate mounted to be rotatable leftward and rightward on the upper surface of the base plate, on which the test body is seated and fixed, and an adapter fixed to the upper surface of the tip of the base plate and performing support for leftward and rightward rotation with the tip of the rotating plate inserted in the space formed by the step formed on the bottom surface.

Description

[0001] Sled Impact Test Apparatus [0002]

The present invention relates to a sled impact test apparatus for impact test of a test body, and more particularly, it is configured such that a rotation plate equipped with a test body can be easily mounted on a base plate and a rotation angle of a rotation plate is easily controlled.

In general, when a car maker first develops a new car, it conducts a variety of safety tests to check the safety of the developed vehicle. This is done by setting a certain standard and checking the completeness according to whether or not the standard is met.

The safety of a vehicle is related to the life of a human being, and can be said to be the most influential factor in the completeness of the vehicle. In many countries, the most stringent standards are applied to the safety of such a vehicle.

These safety tests include seat safety tests, dummy test durability tests, airbag operation tests, and door lock device deformation tests. These tests are designed to be carried out on actual vehicle bodies The test is carried out through a sled impact test device with all the components mounted.

Such a sled impact test apparatus is a device that reproduces the impact amount and the deceleration pattern received by the vehicle as it is in the actual vehicle crash test, and has the effect of saving manpower, time, and budget in the actual vehicle crash test, A part of the vehicle body to be tested is mounted on the sled which can be retracted on the sled and the safety related parts (i.e., airbags, seat belts, sheets, etc.) are mounted inside the vehicle body, The impact piston located at the front of the sled makes the impact and deceleration at the time of actual vehicle collision be reproduced to the body and other mounted products mounted on the sled at the sled price according to the impact value and deceleration pattern at the time of actual vehicle collision, The excavation value, the displacement, and the behavior are collected.

2 is a perspective view showing a sled according to an apparatus for testing a collision test of a mock-up shown in FIG. 1; FIG.

1, a conventional sled impact test apparatus for a vehicle has a sled 20 slidably mounted on a rail block 10 fixed to a bottom surface of a test room, The test body 30 is fixedly mounted in the longitudinal direction.

An impact test equipment 41 for reproducing a body pulse at the time of an actual vehicle collision is installed in front of the sled 20 by using the impact piston 40 operated by high pressure compressed air to charge the sled 20 Respectively.

However, since the test body 30 is fixed to the upper portion of the sled 20 such that the sled 20 is fixed to the front of the sled 20, The collision test can not be performed, and the collision test at various rotational angles can not be further performed.

Therefore, it is impossible to reproduce the sled test apparatus having the same test conditions as those at the time of actual vehicle collision, so that the impact value of the vehicle occupant against the impact that may occur during the rotation of the actual vehicle, the displaced forward displacement, It is not possible to acquire accurate test data for the test results.

2, the sled is divided into the upper sled 21 and the lower sled 23 and the upper sled 21 is provided with the upper end of the rotation angle crystal body 25 And a lower fixing part 27 having a groove formed therein is fixed to the lower sled 23. As shown in Fig. And the lower end of the rotation angle crystal body 25 is inserted into the groove of the lower fixing part 27 so as to be protruded to selectively reproduce a rotation impingement angle at a predetermined angle.

Accordingly, the upper sled 21 to which the test body 30 is fixed can be rotated at a variable variable angle, and the upper sled 21 is fixed to the lower sled 23 while being rotated at a predetermined angle, The sled 23 can be moved in the direction of the impact piston 40 or the impact of the vehicle body can be reproduced by rotating the shock test piston 40 with the test body.

In this way, when the vehicle is fixed to the upper sled, the upper sled is rotated by an angle at which the impact test is to be performed, thereby obtaining various information on the impact that may be generated when the actual vehicle is rotated.

However, even in the case of such a sled impact test apparatus, as the upper sled is rotated in a state fixed to the rotating crystal body, the test is inevitable regardless of the size of the test body. That is, the test car body corresponding to a small actual car and the test car body corresponding to a large real car are mounted on the same upper sled, and thus the reliability of the test data deteriorates as the test proceeds.

Korean Patent Publication No. 10-2006-0033539 (published on April 19, 2006)

SUMMARY OF THE INVENTION The present invention has been made in order to solve the problems of the conventional art as described above, and it is an object of the present invention to provide a rolling device, The purpose is to provide a test apparatus.

In order to accomplish the above object, the present invention provides a sled impact test apparatus comprising: a base plate fixed to a block movable in a front and rear direction; a base plate rotatably mounted on a top surface of the base plate in a lateral direction, And an adapter which is fixed to the upper end surface of the base plate and which is formed by a step formed on the bottom surface, and which supports the tip of the rotation plate so as to be rotatable in the left and right direction.

Further, according to a preferred embodiment of the present invention, an angle scale is displayed on the upper surface of the adapter so that the rotation angle of the rotation plate can be known.

According to a preferred embodiment of the present invention, a stud pin fixed upwardly on an upper surface of a base plate, a stud holder formed with a V-groove opened frontward to surround the stud pin, When the rotary plate is seated on the upper surface of the base plate and then is pushed forward, the stud pin enters the inside of the V groove formed in the stud holder so that the center of the stud pin aligns with the inner center of the V groove, In the left and right direction.

According to a preferred embodiment of the present invention, the pusher further includes a pusher which pushes the rotary plate so that the tip of the rotary plate, which is fixed to the rear end of the base plate and is seated on the upper surface of the base plate, .

According to a preferred embodiment of the present invention, the pusher includes a conveying block in contact with the rear end of the rotating plate, and a push block which is fixed to the rear end of the base plate to guide the forward and backward movement of the conveying block located inside the longitudinally formed slide groove And a first screw which is screwed to the first fixing body and moves in the forward and backward direction by rotation and presses the transport block to advance the rotary plate.

According to a preferred embodiment of the present invention, a puller is fixed to the rear end of the base plate and pulls back the rotation plate mounted on the base plate to pull the tip of the rotation plate out of the step space of the adapter.

According to a preferred embodiment of the present invention, the puller is provided with a pull body fixed to the rear end of the rotary plate, a conveying block to be matched with the pull body, and a forward movement of the conveying block located inside the longitudinally formed slide groove And a first screw which is screwed to the first fixing body and moves in the rearward direction by rotation and is engaged with the transport block to pull the transport block backward.

According to a preferred embodiment of the present invention, a pressure plate larger than the diameter of the first screw is fixed to the tip of the first screw, and a groove is formed in the transport block to insert the pressure plate and the tip of the first screw, So that the transport block is also moved backward by the backward movement of the first screw.

Further, according to a preferred embodiment of the present invention, a long hole is formed in the ratchet body, and a projection inserted into the long hole is formed on the upper surface of the transfer block so that the projection is inserted into the long hole and aligned.

According to a preferred embodiment of the present invention, there is further provided a rotating plate and a rotor installed on the base plate to push the rotating plate to rotate in the left-right direction.

According to a preferred embodiment of the present invention, there is provided a rotor having a rotor fixed to a rear end of a rotating plate and a rotor plate fixed to a rear end of the base plate, The second screw further includes a pusher and a second screw threaded through the rotor so as to penetrate therethrough in a width direction of the rotor. The second screw is linearly moved by rotation to generate a repulsive force generated by pressing the pusher located on the side of the rotor Thereby rotating the rotating plate.

According to a preferred embodiment of the present invention, there is provided an adapter comprising: a second fixing body fixed to an upper surface of an adapter; a rotor fixed to a front end of the rotation plate; And a third screw for rotating the rotating plate by pressing the rotor while moving linearly.

According to a preferred embodiment of the present invention, the second fixture is composed of a lower block fixed to the upper surface of the adapter and having a plurality of projections formed upwardly, and a plurality of holes, which are seated on the upper surface of the lower block and into which the projections of the lower block are inserted And the third screw is screwed in the width direction of the upper block.

According to a preferred embodiment of the present invention, tabs and bolt holes are formed in the base plate with the same radius around the stud pins, bolt holes are formed in the rotation plate corresponding to the tabs and bolt holes of the base plate, The bolt inserted into the bolt hole of the rotating plate is fastened to the tab of the base plate or inserted into the bolt hole of the base plate while the plate is rotated in the left and right direction.

According to a preferred embodiment of the present invention, a support base for supporting the front surface of the test body is fixed to the top surface of the tip of the rotation plate.

As described above, the sled impact test apparatus according to the present invention can easily adjust the test body in the direction of impact on the test body, and can be configured to push or pull the rotary plate onto the base plate, And it is easy to work.

1 is a view showing an apparatus for testing a collision of a vehicle simulation according to a conventional example,
FIG. 2 is a perspective view showing a sled according to the apparatus for testing collision simulation of FIG. 1. FIG.
3 is a conceptual diagram showing a sled impact test apparatus according to an embodiment of the present invention,
FIG. 4 is a plan view showing a state where the test body is rotated in a state where the test body is fixed to the sled impact test apparatus shown in FIG. 3,
5 is a front view showing a state where the test body is fixed to the sled impact test apparatus shown in FIG.
6 is a plan view of the base plate,
7 is a perspective view showing an adapter mounted on the base plate shown in Fig. 6,
8 is a plan view showing a rotation plate,
Fig. 9 is a front view of the state in which the rotary plate is seated on the base plate in Fig. 8;
10 is a perspective view showing a pusher for pushing the rotation plate in mounting the rotation plate on the base plate,
11 is a front view of a state in which the rotation plate is pushed in a state where the pusher shown in Fig. 10 is mounted on the base plate,
12 is a perspective view showing a puller pulling a rotating plate,
13 is a front view of a state in which the puller shown in Fig. 12 is mounted on the base plate and the rotating plate is pulled.
14 is a perspective view showing a rear rotor for rotating the rotary plate,
Fig. 15 is a plan view showing a state in which the rotating plate is rotated using the rear rotor shown in Fig. 14,
16 is a perspective view showing a front rotor for rotating the rotary plate,
17 is a plan view showing a state in which the rotary plate is rotated using the front rotor shown in Fig.

Hereinafter, preferred embodiments of the sled impact test apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

3 is a conceptual view showing a sled impact test apparatus according to an embodiment of the present invention, and FIG. 4 is a state in which a test body is rotated in a fixed state in the sled impact test apparatus shown in FIG. And FIG. 5 is a front view showing a state where the test body is fixed to the sled impact test apparatus shown in FIG. 6 is a plan view showing the base plate, Fig. 7 is a perspective view showing the adapter mounted on the base plate shown in Fig. 6, Fig. 8 is a plan view showing the rotation plate, Fig.

FIG. 10 is a perspective view showing a pusher for pushing the rotation plate when the rotation plate is mounted on the base plate, and FIG. 11 is a perspective view showing a state in which the rotation plate is pushed in a state where the pusher shown in FIG. Fig. 12 is a perspective view showing a puller pulling a rotating plate, and Fig. 13 is a front view showing a state in which the rotating plate is pulled while the puller shown in Fig. 12 is mounted on the base plate.

Fig. 14 is a perspective view showing a rear rotor for rotating the rotary plate, Fig. 15 is a plan view showing a state in which the rotary plate is rotated using the rear rotor shown in Fig. 14, FIG. 17 is a plan view showing a state in which the rotary plate is rotated using the front rotor shown in FIG. 16. FIG.

3 to 5, the sled impact testing apparatus includes a moving block 110 moving along a rail 111 fixed to a laboratory floor, a base plate (not shown) fixed on the upper surface of the moving block 110, The rotation plate 130 is mounted on the upper surface of the base plate 120 and rotatably mounted on the upper surface of the base plate 120. When the rotation plate 130 is mounted on the base plate 120, A pusher 140 and a puller 150 for adjusting the rotation of the rotary plate 130 and rotors 160 and 161 for fine rotation of the rotary plate 130. The rotors 160 and 161 are divided into a front rotor 160 for rotating the tip of the rotating plate 130 and a rear rotor 161 for rotating the rear end of the rotating plate 130.

In the sled impact test apparatus thus configured, the rotary plate 130 fitted with the test body 101 is mounted on the base plate 120 in a state in which the rotary plate 130 suitable for various test bodies 101 is prepared and prepared. As the impact test is performed while replacing, the reliability of the data according to the test is increased.

In the following, a sled impact test apparatus constructed as described above will be described in detail.

The moving block 110 moves along the rail 111 installed on the floor of the laboratory and the shock test equipment (41 of FIG. 1) is located in front of the rail 111 and the impact piston (40 of FIG. 1) So as to apply a shock to the distal end of the moving block 110 while contracting or contracting.

The base plate 120 is fixed to the upper surface of the moving block 110. As shown in FIG. 6, the base plate 120 has a flat plate structure, in which tabs 120T and bolt holes 120H for fixing the adapter 180 and the rotation plate 130 located on the upper surface are formed.

A stud pin 121 is fixed to the center of the upper surface of the base plate 120 so that the rotation plate 130 is rotatable around the stud pin 121. When the rotation plate 130 rotates A bolt hole 130H is formed corresponding to the edge of the arc of the tip end of the rotation plate 130 so as to be fixed in the state of FIG.

An adapter 180 capable of fitting the tip of the rotation plate 130 is fixed to the tip of the base plate 120. As shown in FIG. 7, a tip arc of the rotation plate 130 A corresponding step 181 is formed. Therefore, when the adapter 180 is fixed to the top surface of the base plate 120, a space S corresponding to the height of the step 181 of the adapter 180 is formed and the tip of the rotation plate 130 is connected to the adapter 180 And is sandwiched in the space S formed by the stepped portion 181. As described above, the step 181 is formed so as to correspond to the tip arc of the rotation plate 130, so that the rotation plate 130 does not interfere with the rotation about the stud pin 121.

An angle scale 183 is formed on the adapter 180 so that the rotation angle of the rotation plate 130 can be checked.

8, the rotary plate 130 is formed in an arcuate shape at the front end and the rear end, and the bolt hole 130H and the tab 130T are alternately formed along the edge of the circular arc. A stud holder 131 is formed at the center of the rotation plate 130. The stud holder 131 is formed with a V groove 133 opened toward the front.

The stud holder 131 is configured such that the stud pin 121 is located inside the V groove 133 of the stud holder 131 when the rotary plate 130 is seated on the upper surface of the base plate 120, Is formed by rotating the stud holder 131 along the circumferential surface of the stud pin 121 while the stud holder 131 is supported by the stud pin 121 when the stud holder 121 rotates about the stud pin 121.

Holes 134H corresponding to the bolt holes 120H formed on both lateral sides of the center of the length of the base plate 120 are formed on the right and left sides in the width direction at the center of the length of the rotary plate 130, The holes 134H are formed so as to correspond to the bolt holes 120H of the base plate 120 when the rotation plate 130 rotates, Lt; / RTI >

A supporting base 123 supporting the test body 101 is fixed to the upper surface of the rotating plate 130. The supporting base 123 is assembled in the form of a right angle triangular column as shown in FIG. And a front end of the test body 101 is fixed in contact with the test body 101 fixed to the rotary plate 130 on the other surface.

The rotating body 130 is fixed to the upper surface of the base plate 120 while the tip of the rotating plate 130 is sandwiched between the steps 181 of the adapter 180 And the position of the stud pin 121 is adjusted by the pusher 140 so that the stud pin 121 is positioned at the center of the V groove 133 of the stud holder 131.

10 and 11, the pusher 140 includes a first fixing body 141 fixed to a rear end side of the base plate 120, a second fixing body 141 fixed to the rotation plate 130 through the first fixing body 141, A first screw 171 moving forward and backward toward the rear end of the rotating plate 130 and a first screw 171 moved forward and back by the first screw 171 in accordance with forward and backward movements, (147).

The bolts are fastened to the tabs 120T formed on the base plate 120 with the bolts passing through the bolt holes formed in the flange 141F, do. Accordingly, the first fixing body 141 is fixed to the base plate 120, and the first screw 171 is movable in the forward and backward directions while rotating. The conveying block 147 is located in the first fixing unit 141 and a movable slide groove 143 is formed in the first fixing unit 141. The conveying block 147 located in the slide groove 143 is moved forward And the rotary plate 130 in contact with the conveying block 147 is also moved forward.

The pressure plate 145 is formed at the end of the first screw 171 larger than the diameter of the first screw 171 and the end of the first screw 171 and the groove (147H) is formed. Accordingly, the pressure plate 145 inserted in the groove 147H pushes the transfer block 147 forward or backward according to the forward and backward movement of the first screw 171.

The rotary plate 130 mounted on the upper surface of the base plate 120 by the operation of the pusher 140 is moved to the space S formed by the step 181 of the adapter 180 while advancing, And the stud pin 121 enters the inside of the V groove 133 formed in the stud holder 131.

Meanwhile, in order to replace the mounted rotary plate 130, the rotary plate 130 located on the upper surface of the base plate 120 must be taken out.

For this purpose, the rocking body 151 is connected to the transport block 147 fixed to the base plate 120, and the rotary plate 130 is taken out.

12 and 13, the fuller 150 uses the same first fixing unit 141, the first screw 171 and the transfer block 147 as described above, and rotates the rotary plate 130, And a sucking body 151 coupled to the conveying block 147 to draw the rotating plate 130 in a fixed state.

A bolt hole corresponding to the tab formed at the rear end of the rotator plate 130 is formed at the front end and a slot 153 is formed at the center of the plate structure extending rearward.

In the slot 153, a protrusion 149 formed on the upper surface of the transport block 147 is inserted into the slot 147 and aligned.

The tip of the string body 151 is fixed to the rear end of the rotary plate 130 and the first screw 171 is rotated in a state in which the projection 149 of the transfer block 147 is aligned with the slot 153 When the transfer block 147 is retracted, the matched prong body 151 is retracted and the rotary plate 130 moves backward and is drawn out from the space S between the adapter 180 and the base plate 120. The stud pin 121 is also drawn out of the V groove 133 of the stud holder 131. The rotation plate 130 thus drawn is lifted by a hoist or the like and is transported out of the base plate 120 and mounted through the pusher 140 in a state in which another rotation plate is seated on the upper surface of the base plate 120.

On the other hand, in order to perform the impact test while the test body 101 is rotated at a predetermined angle, the rotation plate 130 mounted on the base plate 120 is rotated The plate 130 is seated on the base plate 120. That is, when the rotary plate 130 is lifted up by the hoist and is mounted on the upper surface of the base plate 120, when the pin is inserted into the bolt hole formed at the angle indicated by the adapter 180 and the lifted rotary plate 130 is lowered, The rotation plate 130 is seated in a state of being rotated at a predetermined angle when it is rotated and inserted to be inserted into the bolt hole formed at the set angle.

Then, the rotation plate 130 is mounted using the pusher 140 described above.

In order to finely adjust the rotation angle of the rotation plate 130, in the present invention, the front rotor 160 and the rear rotor 161 are rotated in the same direction, And the rear rotor 161 rotates the rotary plate 130 using the first fixing body 141 fixed to the base plate 120 and the front rotor 160 rotates the adapter 180 And the rotary plate 130 is rotated using the second fixing body 190 fixed on the upper surface.

The rear rotor 161 and the front rotor 160 will be described in detail below.

14 and 15, the front end of the rear rotor 161 is positioned on the rear upper surface of the rotation plate 130, and a bolt hole is formed corresponding to the tab 130T formed on the rotation plate 130 And the rear end of the rear rotor 161 is conveyed by the second screw 172 which faces the side face of the conveying block 147 of the first fixing body 141 and penetrates the rear end of the rear rotor 161 in the width direction And is located in contact with the side surface of the block 147.

When the bolt is inserted into the bolt hole of the rear rotor 161 and is fastened to the tab 130T of the rotary plate 130, the rear rotor 161 is fixed to the rotary plate 130. In this state, The rotation plate 130 is rotated by the reaction force of the second screw 172 by pressing against the side surface of the transport block 147 of the first fixing body 141 by advancing the transport block 147 in the direction in which the transport block 147 is positioned, As shown in FIG.

As such, the rear rotor 161 can be finely adjusted so that the rotary plate 130 is properly positioned by finely rotating the rear end of the rotary plate 130.

16 and 17, the rear end of the front rotor 160 is positioned on the top surface of the rotation plate 130 and corresponds to the tab 130T formed on the rotation plate 130, And the front end of the front rotor 160 extends to the upper surface of the adapter 180. [

The second fixing body 190 is fixed to the upper surface of the adapter 180.

The second fixing body 190 includes a lower block 191L fixed to the upper surface of the adapter 180, an upper block 191H which is seated on the upper portion of the lower block 191L and is matched with the upper block 191H, And a third screw 173 that moves forward and backward by rotation and pushes the front rotor 160 and pushes it.

Particularly, as shown in FIG. 16, the lower block 191L has four projections 195 having a "T" shape in cross section on its upper surface. Four bolt holes are formed in the lower block 191L and the bolts inserted in the bolt holes are fastened to the tabs formed on the adapter 180 so that the lower block 191L is fixed to the upper surface of the adapter 180. [ Here, the upper horizontal portion of the projection 195 is referred to as a "head 195H ", and the vertical portion is referred to as a" web 195W ".

Four holes 197 into which the protrusions 195 of the lower block 191L are inserted are formed in the upper block 191H. The hole 197 is also formed in the shape of a 'T', and the lower end of the hole 197 is inserted into the head 195H of the projection 195 so that the projection 195 can be inserted through the lower end of the hole 197 And the upper end of the hole 197 has a structure extended to both sides. The protrusion 195 of the lower block 191L is inserted into the hole 197 of the upper block 191H and the upper block 191H is seated on the upper surface of the lower block 191L, A clearance capable of moving in the left and right direction is formed by a difference between the width of the web 195W of the upper portion 195 and the lower end width of the hole 197.

This is because when the front rotor 160 is pressed by the third screw 173 passing through in the width direction of the upper block 191H, the upper block 191H moves by the clearance, And the head 195H of the projection 195 is engaged with the jaw so that the upper block 191H does not deviate upward.

The front rotor 160 fixed to the tip of the rotary plate 130 is rotated by the third screw 173 passing through the upper block 191H of the second fixing body 190 fixed to the adapter 180 in the width direction, And rotates the rotating plate 130. As shown in FIG.

As described above, as the rotational position of the rotating plate 130 is finely adjusted by the front rotor 160 and the rear rotor 161, the rotation plate 130, which is seated on the base plate 120, The rotation angle can be finely adjusted.

The following explains the use and operation of the sled impact test system constructed in this way.

And the test body is fixed to the upper surface of the rotating plate 130.

The rotation plate 130 is mounted on the upper surface of the base plate 120 using a hoist or the like so that the distance between the tip of the rotation plate 130 and the adapter 180 is maintained at about 5 mm. And the rotary plate 130 is seated on the upper surface. 5, the rotation plate 130 is rotated at an angle to be tested as shown in FIG. 4, as shown in FIG. 5, according to the impact direction of the test body 101, 120, respectively.

And pushes the rotary plate 130 forward using the pusher 140. 5, if the longitudinal center line of the rotary plate 130 and the longitudinal center line of the base plate 120 coincide with each other, the pusher 140 pushes the rotary plate 130 to move the rotary plate 130 The tip of the rotary plate 130 is inserted into the space S of the step 181 of the adapter 180 and at the same time the stud pin 121 is positioned at the center of the V groove 133 of the stud holder 131, The rotating plate 130 moves forward, so that there is no serious problem in positioning the rotating plate 130 in a correct position.

4, when the rotary plate 130 is pushed by the pusher 140 in a state in which the rotary plate 130 is seated at a rotation angle, when the rotary plate 130 is pushed with respect to the center line of the rotary plate 130, The angle of the rotary plate 130 is changed as the rotary plate 130 advances and it is necessary to finely adjust the angle by the front and rear rotors 160 and 161 to correct the position.

When the rotational angle is finely corrected using the rear rotor 161, the rear rotor 161 is fixed to the rear end of the rotational plate 130 as shown in Figs. 14 and 15, and the rear rotor 161 The second screw 172 of the first fixing body 141 is rotated to press the transfer block 147 of the first fixing body 141 to rotate the rotation plate 130 by the reaction.

16 and 17, when the front rotator 160 is fixed to the tip of the rotation plate 130 and the adapter 180 is rotated, When the third screw 173 of the second fixing body 190 is rotated and pressed, the rotation plate 130 is rotated by the reaction.

When the rotation plate 130 is positioned at a desired direction and angle, the bolt is inserted into the bolt hole 130H formed in the rotation plate 130 and screwed into the tab 120T formed on the base plate 120 And fixed.

After the impact test is performed to secure necessary data, the bolts for fastening the base plate 120 and the rotary plate 130 are disassembled and the bolts for fastening the first fixing body 141 fixed to the rear end of the base plate 120 A bolt is inserted into a bolt formed in the tip of the needle body 151 and the bolt is inserted into the rotary plate 130. Then, And then the first screw 171 is rotated to draw the rotary plate 130 backward.

When the tip of the rotation plate 130 comes out from the space S of the step 181 of the adapter 180, the rotary plate 130 is lifted and replaced using a hoist or the like.

On the other hand, holes for mounting a caster are formed on the bottom of the edge of the rotary plate so that the castor can be used to transfer the rotary plate 130.

101: Test body
110: Moving block
120: base plate
123: Support
130: Rotating plate
140: Pusher
141: first fixing body
150: Puller
160: front rotor
161: rear rotor
180: Adapter
190: Second fixed body

Claims (15)

A base plate 120 fixed to the block 110 movable in the forward and backward directions,
A rotation plate 130 rotatably mounted on the upper surface of the base plate 120 in the left and right direction and having a test body 101 mounted thereon,
And an adapter 180 fixed to the top surface of the base plate 120 and supporting the rotation plate 130 in such a manner that the tip of the rotation plate 130 is rotatable in the left and right direction in a space S formed by a step 181 formed on the bottom surface And a sled impact test apparatus.
The method according to claim 1,
And an angle scale (183) is displayed on the upper surface of the adapter (180) so that the rotation angle of the rotation plate (130) can be known.
The method according to claim 1,
A stud pin 121 fixed upward on the upper surface of the base plate 120,
And a stud holder 131 fixed to the bottom surface of the rotary plate 130 and having a V-groove 133 opened toward the front so as to surround the stud pin 121,
When the rotary plate 130 is seated on the upper surface of the base plate 120 and then is pushed forward, the stud pin 121 enters the inside of the V-groove 133 formed in the stud holder 131 so that the center of the stud pin 121 And the inner center of the V groove (133) is aligned so that the rotary plate (130) is rotatable in the left and right direction around the stud pin (121).
4. The method according to any one of claims 1 to 3,
The pusher pushes the rotary plate 130 so that the tip of the rotary plate 130 fixed to the rear end of the base plate 120 and seated on the upper surface of the base plate 120 is inserted into the stepped space S of the adapter 180. Further comprising a pusher (140).
5. The method of claim 4,
The pusher 140 guides the forward and backward movement of the transport block 147 contacting the rear end of the rotary plate 130 and the transport block 147 located inside the slide groove 143 formed in the longitudinal direction, The first fixing body 141 is screwed to the first fixing body 141 and is moved forward and backward by rotation to press the transfer block 147 to move the rotary plate 130 forward And a first screw (171) for making a sled impact.
4. The method according to any one of claims 1 to 3,
A puller 130 that is fixed to the rear end of the base plate 120 and pulls the rotation plate 130 mounted on the base plate 120 backward to draw the tip of the rotation plate 130 out of the step space S of the adapter 180 (150). ≪ / RTI >
The method according to claim 6,
The puller 150 includes a needle body 151 fixed to the rear end of the rotary plate 130, a transfer block 147 matching the ratchet body 151, and a slide groove 143 formed in the longitudinal direction A first fixing body 141 which guides the forward movement of the conveying block 147 and is fixed to the rear end of the base plate 120 and a second fixing body 141 which is screwed to the first fixing body 141, And a first screw (171) coupled with the transport block (147) to pull the transport block (147) backward.
8. The method of claim 7,
A pressing plate 145 having a diameter larger than the diameter of the first screw 171 is fixed to the tip of the first screw 171 and a pressing plate 145 is fixed to the moving block 147, And the conveying block 147 is also moved backward by the backward movement of the first screw 171 as the pressure plate 145 is inserted into the groove 147H.
8. The method of claim 7,
A protrusion 149 is formed in the needle body 151 and inserted into the slot 153 on the upper surface of the transfer block 147 so that the protrusion 149 is inserted into the slot 153, And a sled impact test apparatus.
4. The method according to any one of claims 1 to 3,
Further comprising rotators (160, 161) installed on the rotating plate (130) and the base plate (120) to push the rotating plate (130) to rotate in the left and right direction.
11. The method of claim 10,
A rotor 161 fixed to the rear end of the rotation plate 130,
A pusher 140 fixed to the rear end of the base plate 120 and pushing the tip of the rotation plate 130 mounted on the upper surface of the base plate 120 to be inserted into the stepped space of the adapter 180,
Further comprising a second screw (172) screwed into the rotor (161) so as to penetrate in the width direction thereof,
Characterized in that the rotary plate (130) is rotated by a repulsive force generated by pushing the pusher (140) located at the side of the rotor (161) while the second screw (172) Device.
11. The method of claim 10,
A second fixing body 190 fixed to the upper surface of the adapter 180,
A rotor 160 fixed to the tip of the rotation plate 130,
And a third screw 173 screwed into the second fixing body 190 so as to penetrate in the width direction and linearly moved by rotation to press the rotor 160 to rotate the rotation plate 130 A sled impact test device.
13. The method of claim 12,
The second fixing body 190 includes a lower block 191L which is fixed to the upper surface of the adapter 180 and has a plurality of projections 195 formed upward,
And an upper block 191H which is seated on the upper surface of the lower block 191L and in which the holes 197 into which the protrusions 195 of the lower block 191L are inserted are formed,
And the third screw (173) is screwed in the width direction of the upper block (191H).
The method of claim 3,
The tab 120T and the bolt hole 120H are formed in the base plate 120 at the same radius around the stud pin 121. The tab 120T of the base plate 120 and the bolt hole 120H are formed in the rotation plate 130, The bolts 130H and 134H are formed in correspondence with the base plate 120H and the bolts inserted into the bolt holes 130H and 134H of the rotation plate 130 in the state in which the rotation plate 130 is rotated in the left- Is fastened to the tab (120T) of the base plate (120) or inserted into the bolt hole (120H) of the base plate (120).
4. The method according to any one of claims 1 to 3,
Wherein a support base (123) for supporting a front surface of the test body (101) is fixed to the top surface of the tip of the rotation plate (130).

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