KR20180118268A - Actuator for automobile impact test - Google Patents

Abstract

The present invention relates to an actuator for a vehicle collision test, used for realizing a collision test of a vehicle without an actual collision of a vehicle. More specifically, the present invention relates to a device for generating an impact to test movement of a vehicle caused by the impact and the impact in various directions generated in an actual collision test.

Description

[0001] The present invention relates to an actuator for automobile impact test,

The present invention relates to an actuator for crash test of an automobile which is used for reproducing a crash test of an automobile without an actual crash of an automobile. More specifically, the present invention relates to an actuator for crash test, And a device for generating an impact to generate a shock.

The first time a car maker develops a new car, it conducts a variety of safety tests to check the safety of the developed car. It sets a certain standard and checks the completeness according to whether or not it conforms to this standard.

Safety in automobiles is a factor that most affects the completeness of automobiles, especially in relation to human life, and in many countries around the world, the most stringent standards are applied to the safety of such automobiles .

Generally, a suspension system of an automobile includes a chassis spring which connects an axle and a vehicle body, a shock spring that absorbs an impact from the road surface while driving, a shock absorber that absorbs free vibration of the spring, and a stay- .

The reason why such a suspension device is necessary is to cope with the phenomenon of pitching and rolling occurring while the vehicle is running. The term " pitching phenomenon " refers to a phenomenon in which when a vehicle is overrun, . In order to minimize such a pitching phenomenon, it is desirable to maximize the rigidity.

The rolling phenomenon refers to the rotational motion of the vehicle body passing through the center in the longitudinal direction of the vehicle when the vehicle is turning or receiving a wind in the middle of traveling. In order to minimize the rolling phenomenon, it is necessary to maximize the lubrication.

Therefore, a test apparatus is required to cope with such a pitching and rolling phenomenon. Since a conventional test vehicle is fixed on a sled, it is impossible to perform a pitching test, thereby realizing collision of an actual vehicle, There is a problem that leads to a result of an increase in test time and cost.

The following is a typical conventional technique for a pitching simulator for a car.

Korean Patent Laid-Open Publication No. 10-2006-0033539 relates to an automobile impact test apparatus having a pitching rolling function, which comprises a rail block fixed to a bottom surface of a test chamber, And a test body installed on the top surface of the sled to which various components for various types of tests are built and a test body which is operated by high pressure compressed air in front of the sled in accordance with a control signal of the main controller, A sled test apparatus for an automobile comprising an impact test apparatus for reproducing a body-applied pulse at the time of an actual vehicle crash by charging a sled, characterized in that the sled is divided into upper and lower sleds, And the lower end of the lower sled is projectingly engaged with the upper sled to selectively reproduce a rotation impingement angle at a predetermined angle A rotatable angular crystal; A flow unit for connecting the test body and the front end of the upper sled to each other to generate a constant hydraulic pressure bearing force on the test body; And a pitching means for connecting the test body and the rear end of the upper sled to each other and providing a constant hydraulic pressure supporting force to the rear end of the test body so that the collision locus can be changed by the height at which the rear end of the vehicle body rises at the time of the body collision.

In addition, the above-mentioned prior art constitutes a variable spring-damper corresponding to a suspension device of an actual automobile in order to reproduce a pitching phenomenon which is generated differently depending on the center of gravity of the car, the type of the car, and the weight of the car, So that it is possible to reproduce various pitching phenomena and rolling phenomenon occurrence, thereby realizing an actual collision reproduction.

However, in the above-mentioned prior art, the development of an actuator for generating a force for inducing a rolling phenomenon and a pitching moment corresponding to a vertical direction for inducing a pitching phenomenon is somewhat lacking, and continuous research and development This is a required situation.

Korean Patent Publication No. 10-2006-0033539 (April 19, 2006) Korean Patent Publication No. 10-2004-0017666 (Feb. Korean Patent Publication No. 10-2003-0035132 (2003.05.09) Korean Registered Patent No. 10-1711515 (Feb. 23, 2017).

SUMMARY OF THE INVENTION The present invention has been made in order to solve the problems of the prior art of an actuator for an impact test of automobiles, in which a conventional actuator smoothly decelerates a rod, which is instantly moved forward by a pressure such as pneumatic pressure or hydraulic pressure, A problem arises that a part of the cylinder of the actuator which surrounds the outside of the rod may be broken, and the main object thereof is to provide a solution to this problem.

The present invention has been made to solve the above-

A rod having a length in the longitudinal direction of the actuator and having a head at the rear; A pressurizing housing connected to a pressurizing pipe through which a pneumatic pressure acts on the rear, and a hollow cylinder chamber formed in the longitudinal direction of the actuator, the pressurizing housing having the rod inserted into the cylinder chamber from the rear; A first flow path connected to a front of the pressure housing and having a hollow cylinder chamber communicating with a cylinder chamber of a pressurizing housing for introducing an intermediate portion of the rod into the cylinder chamber and having an inlet formed at the rear of the cylinder chamber, A deceleration housing formed with a normally-discharge path communicating the cylinder chamber and the outside; A braking member connected to a front of the deceleration housing and having a braking member having a hollow cylinder chamber communicating with a cylinder chamber of the deceleration housing to allow a front portion of the rod to be inserted into the hollow cylinder chamber and having a brake pad capable of friction with an outer surface of the rod; And an actuator for an automobile crash test.

The actuator for an automobile crash test according to the present invention as described above is characterized in that before a head provided with a rod for instantly moving forward in a cylinder chamber of a pressurized housing by pneumatic or hydraulic pressure reaches a braking housing, The effect of being able to be decelerated in the deceleration housing constructed between the first and second rotary shafts;

As a result, it is possible to prevent collision of the head with respect to the deceleration housing or the braking housing before the braking housing in which the forward movement of the rod is restricted, and to prevent breakage of the cylinder, such as the deceleration housing or the braking housing, Effect can be obtained.

1 is a perspective view showing an actuator for an automobile crash test according to a preferred embodiment of the present invention.
2 is a plan view showing an actuator for an automobile crash test according to a preferred embodiment of the present invention.
3 is a plan sectional view showing an actuator for an automobile impact test according to a preferred embodiment of the present invention.
4 is a sectional view of an AA partial side view showing an actuator for an automobile impact test according to a preferred embodiment of the present invention.
5 is a cross-sectional side view of a part of a BB showing an actuator for an automobile impact test according to a preferred embodiment of the present invention.
6 is a cross-sectional side view of a CC portion showing an actuator for an automobile impact test according to a preferred embodiment of the present invention.
7 is a plan sectional view showing a state before the rod of the actuator for crash test according to the preferred embodiment of the present invention is moved forward.
8 is a plan sectional view showing a state in which the rear end of the head of the actuator for crash test according to the preferred embodiment of the present invention is moved to the inlet of the first flow path.
9A and 9B are plan sectional views showing a case where a load of an actuator for an automobile crash test according to a preferred embodiment of the present invention is first decelerated.
10A and 10B are plan sectional views showing a case where a rod of an actuator for an automobile crash test according to a preferred embodiment of the present invention is secondarily decelerated.
11A and 11B are plan sectional views showing a case where the rod of the actuator for crash test according to the preferred embodiment of the present invention is thirdly decelerated.
12 is a plan sectional view showing a state in which a residual pressure of a cylinder chamber of an actuator for an automobile impact test according to a preferred embodiment of the present invention is discharged.
13 is a plan sectional view showing a state in which the rod of the actuator for crash test according to the preferred embodiment of the present invention returns to the cylinder chamber of the pressure housing.
14 is a graph showing the pressures of respective cylinder chambers of deceleration sections of an actuator for an automobile impact test according to a preferred embodiment of the present invention.

The present invention relates to an actuator for an impact test of an automobile used for reproducing a crash test of an automobile without an actual collision of an automobile, the actuator comprising: a rod 10 having a length in the longitudinal direction of the actuator and having a head 11 at the rear; A pressurizing housing 20 connected to a pressurizing pipe 22 to which a pressure is applied to the rear side and having a hollow cylinder chamber 21 formed therein in the longitudinal direction of the actuator to allow the rod 10 to be inserted from the rear side; A middle portion of the rod 10 is inserted into hollow cylinder chambers 31a and 31b connected to the front of the pressure housing 20 and communicating with the cylinder chamber 21 of the pressure housing 20, A first flow path 32 formed with an inlet 32a at the rear of the cylinder chambers 31a and 31b and a discharge port 32b formed at the front thereof and a first flow path 32 communicating with the cylinder chambers 31a and 31b, A deceleration housing 30 having a passage 33 formed therein; A front portion of the rod 10 is inserted into a hollow cylinder chamber 41 connected to the front of the decelerating housing 30 and communicated with the cylinder chambers 31a and 31b of the decelerating housing 30, And a braking member (44) having a braking member (44) having a brake pad (42) capable of friction with an outer surface of the braking member (10).

First, when the actuator according to the present invention is used as an apparatus for arbitrarily generating a collision force necessary for an impact test of an automobile, it can be used in various types of automobile crash test apparatus. A case in which the actuator according to the present invention is mounted on the pitching simulator for automobile disclosed in Japanese Patent No. 10-1711515 will be described as a preferred embodiment.

That is, the actuator according to the present invention can be used as an apparatus for generating an action force (impact force) for instantaneous change in tilt of an automobile generated at the time of a crash of an automobile.

Specifically, when an automobile, which is an impact object at the time of a collision, is used, impacts and motions are generated in various directions of an automobile at the time of actual collision, and the impact and movement are expressed in general engineering expressions in the directions of X axis, Y axis and Z axis It is done in a corresponding three-dimensional manner.

In this case, the force causing the impact and movement of the automobile may be divided into rolling moment, yawing pitching moment, and yawing moment of the X axis and the Y axis, respectively, Can be used as an actuator for artificially reproducing the pitching moment proposed in the automobile pitching simulator disclosed in Korean Patent No. 10-1711515.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

First, an actuator for crash test according to the present invention comprises a rod 10, a pressurizing housing 20, a decelerating housing 30, and a braking housing 40 macroscopically.

That is, the rod 10 has a structure in which the length is formed in the longitudinal direction of the actuator and the head 11 is provided at the rear, and the rod 10 receives the instantaneous pressing force by the pressure and moves forward.

The longitudinal direction of the actuator means the same direction as the connecting direction of the pressure housing 20, the decelerating housing 30 and the braking housing 40 included in the actuator according to the present invention, 10 in the same direction.

Referring to FIG. 2A, in the following description of the present invention, the rod 10 is moved forward from the right to the left, and the right side of the drawing will be referred to as the rear side and the left side of the drawing will be referred to as the front side.

Specifically, the rod 10 has a predetermined length as shown in FIG. 3 and a head 11 at the rear. The head 11 is connected to the cylinder chamber 21 of the pressurized housing 20, The pressure applied at the back of the head 11 by being hermetically sealed with the inner surfaces of both the cylinder chambers 31a and 31b of the decelerating housing 30 and the cylinder chamber 41 of the braking housing 40 is transmitted to the front of the head 11 So that it does not flow.

The rod 10 extending in front of the head 11 has an outer diameter smaller than that of the head 11 and can move horizontally without interfering with the inner surfaces of all the cylinder chambers. And may be rubbed against the brake pads 42 provided in the braking housing 40.

The front portion of the rod 10 positioned opposite to the connecting portion with the head 11 protrudes forward of the cylinder chamber 41 of the braking housing 40 and is connected to a link guide of a known pitching simulator for a car, You can do the connected configuration.

In addition, the cylinder rod 10 may have various vertical cross-sections such as a circular or polygonal shape as long as the following braking member 44 can appropriately form a frictional force with the brake pads 42, There is formed concavo-convexes formed with grooves and projections in a direction perpendicular to the longitudinal direction or in a direction in which a predetermined inclination angle is formed, so that the frictional force with the brake pad 42 can be increased.

The pressurizing housing 20 is connected to a pressurizing pipe 22 to which a pressure is exerted at the rear, and the rod 10 is inserted into the hollow cylinder chamber 21 formed in the longitudinal direction of the actuator from the rear side As a construction, the rod 10 is instantaneously advanced by a pressure applied to the cylinder chamber 21.

The pressure piping 22 is configured to provide a pressure in the cylinder chamber 21 of the pressure housing 20 and a pressure (hereinafter, referred to as " pneumatic pressure " The pressure applied to the cylinder chamber 21 through the pressure pipe 22 connected to the rear of the cylinder chamber 21 of the pressure housing 20 can be supplied to the rear of the rod 10 So that the head 11 and the rod 10 can be advanced and the advancing force of the advancing rod 10 is connected to the link guide of the known pitching simulator for a car Or acts as an acting force of the weight.

The rod 10 inserted into the cylinder chamber 21 of the pressure housing 20 is formed so that the rear portion of the rod 10 provided with the head 11 is inserted into the rear of the cylinder chamber 21 , And the front portion of the rod (10) is configured to be inserted into the cylinder chamber (41) of the braking housing (40).

The deceleration housing 30 is connected to the front of the pressure housing 20 and is connected to the hollow cylinder chambers 31a and 31b communicating with the cylinder chamber 21 of the pressure housing 20, A first flow path 32 is formed in the rear of the cylinder chambers 31a and 31b and an outlet 32b is formed in the front of the cylinder chambers 31a and 31b, Wherein the cylinder chamber 31a or 31b communicating with the cylinder chamber 21 of the pressure housing 20 is formed in the longitudinal direction of the rod 10 And a first flow path 32 formed to have a length in the same direction as the pressure chamber 20 and capable of flowing a part of the pressure applied from the cylinder chamber 21 of the pressure housing 20 toward the front of the head 11 .

That is, the deceleration housing 30 is provided at the rear of the head 11 provided at the rear of the rod 10 to decelerate the forward movement of the rod 10 moved forward in the cylinder chamber 21 of the pressure housing 20 (A pressure higher than the pressure on the front side of the head 11, which is contained in the rear side of the head 11, (Which may vary depending on the strength of the impact force by the rod 10).

The rear portions of the cylinder chambers 31a and 31b formed in the decelerating housing 30 communicate with the front of the cylinder chamber 21 of the pressure housing 20 and the front portions of the cylinder chambers 31a and 31b of the decelerating housing 30 A portion other than the through hole through which the rod 10 penetrates is maintained in a closed state (provided that the following discharge path 33 is formed).

At this time, the deceleration housing 30 has cylinder chambers 31a and 31b formed therein and connected to the front of the pressure housing 20, forming an inner periphery integral with the cylinder chamber 21 of the pressure housing 20 And the cylinder chambers 31a and 31b of the deceleration housing 30 are arranged such that the head 11 provided in the rod 10 is inserted into the rear of the cylinder chamber 21 of the pressure housing 20, The intermediate portion of the rod 10 is inserted and can be made integral with the pressure housing 20 according to the judgment of a person skilled in the art.

The head 11 moved in the advancing direction by the high pressure applied from the cylinder chamber 21 of the pressure housing 20 is connected to the deceleration housing 30 through the cylinder chambers 31a and 31b A portion of the high pressure inside the cylinder chamber 21 on the rear side of the head 11 can be flowed in the form of a bypass in front of the head 11, (32) are formed.

3 and 4, the first flow path 32 has a length in the longitudinal direction of the decelerating housing 30 and is formed in the decelerating housing 30, and the decelerating housing 30, The inner diameter of the cylinder chambers 31a and 31b is smaller than that of the cylinder chambers 31a and 31b.

At this time, the inlet 32a of the first flow path 32 is formed on the rear side of the cylinder chambers 31a and 31b of the deceleration housing 30, and the outlet 32b of the first flow path 32 is formed Is formed on the front side of the cylinder chamber (31a, 31b) than the inlet (32a).

The distance between the inlet 32a and the outlet 32b of the first flow path 32 is greater than the thickness of the head 11 (the distance between the front end and the rear end of the head 11) Is configured such that the front end of the head 11 at a position where the rear end of the head 11 passes through the inlet 32a does not reach the outlet 32b.

As shown in FIG. 4, the first flow path 32 is formed radially around the cylinder chambers 31a and 31b of the deceleration housing 30, and the deceleration housing 30 So that part of the high-pressure pressure inside the cylinder chambers 31a, 31b of the cylinder head 31 can be uniformly flowed to the front of the head 11.

Specifically, when a high pressure is supplied to the cylinder chamber 21 of the pressure housing 20, the pressure inside the cylinder chamber 21 of the pressure housing 20 is lowered to the cylinder chambers 31a, 31b so that the rod 10 and the head 11 move forward toward the cylinder chambers 31a, 31b of the decelerating housing 30. At this time, when the head 11 of the advancing rod 10 passes through the inlet 32a of the first flow path 32, the pressure of the high pressure inside the cylinder chamber 21 of the pressure housing 20 A part of the refrigerant flows into the first flow path 32 through the inlet 32a of the first flow path 32 and then is discharged to the discharge port 32b of the first flow path 32. [

A part of the pressure introduced into the cylinder chambers 31a and 31b of the deceleration housing 30 through the first flow path 32 is transmitted to the cylinder chamber 31a of the deceleration housing 30 corresponding to the front of the head 11, The braking force (buffering force) against the forward movement of the head 11 is increased by a predetermined pressure (the pressure is lower than the pressure of the cylinder chamber 21 of the pressure housing 20) Thereby preventing the front end of the head 11 from colliding with the front side wall of the deceleration housing 30 (or the rear side wall of the following braking housing 40) by decelerating the forward movement speed of the rod 10, .

When the rod 10 continues to move forward in the cylinder chambers 31a and 31b of the deceleration housing 30 and the front end of the head 11 closes the outlet 32b of the first flow path 32, The flow of the pressure of the head 11 through the first flow path 32 is stopped and the first flow path 32 is communicated with the cylinder chamber 21 of the pressure housing 20 . At this time, the braking force for the forward movement of the head 11 is transmitted to the deceleration housing 30 at the front side of the head 11 before the front end of the head 11 blocks the discharge port 32b of the first flow path 32, And is continuously formed by the air filled in the cylinder chambers 31a and 31b.

The constant discharge passage 33 formed in the deceleration housing 30 is configured to communicate with the cylinder chambers 31a and 31b of the deceleration housing 30 and has an inner diameter smaller than that of the cylinder chambers 31a and 31b The cylinder chamber 21 of the pressure housing 20 and the cylinder chamber 21 of the deceleration housing 30 in which advancement of the rod 10 provided with the head 11 is simultaneously positioned in front of the head 11, (31a, 31b) is discharged to the outside.

That is, the normally discharging path 33 always communicates with the cylinder chambers 31a and 31b of the decelerating housing 30 as shown in FIG. 6, and the head 11 is connected to the normally discharging path 33 31b of the deceleration housing 30 corresponding to the rear of the head 11 is discharged to the outside of the cylinder chamber 31a, And when the head 11 is positioned at another predetermined portion of the cylinder chamber 31a or 31b of the decelerating housing 30 corresponding to the front of the normally discharging path 33, Air contained in the cylinder chambers (21, 31a, 31b) can be discharged to the outside.

More specifically, when the head 11 moves forward from the cylinder chamber 21 of the pressure housing 20 to the cylinder chambers 31a and 31b of the deceleration housing 30, the pressure housing 20 and the deceleration housing 30 The air contained in the cylinder chambers 21, 31a and 31b of the pressure chambers 30 is discharged through the discharge passage to reduce the resistance to the head 11 moving forward in the cylinder chamber 21 of the pressure housing 20 The head 11 and the rod 10 can be moved forward as fast as possible in the cylinder chamber 21 of the pressure housing 20. [

Of course, a part of the pressure, which flows to the cylinder chambers 31a and 31b of the deceleration housing 30 corresponding to the front of the head 11 through the first flow path 32, The cylinder chambers 31a and 31b of the deceleration housing 30 formed by the continuous narrowing of the cylinder chambers 31a and 31b of the deceleration housing 30 due to the forward movement of the head 11, Since the pressure increase rate is larger than the pressure decrease rate due to the air discharged to the outside from the cylinder chambers 31a and 31b of the decelerating housing 30 through the normal discharge passage 33, The braking force (buffering force) for the forward movement of the head 11 by the braking force can be maintained.

In the present invention, as the rod 10 having the head 11 is moved forward in the cylinder chamber 21 of the pressurizing housing 20, the forward movement speed of the rod 10 can be maintained as fast as possible And the braking force is formed on the rod 10 after the head 11 passes through the inlet 32a of the first flow path 32 formed in the deceleration housing 30, The decelerating force of the rod 10 moving forward in the cylinder chambers 31a and 31b of the decelerating housing 30 may be further increased and the front end of the head 11 may be connected to the deceleration housing 30, The second flow path 34 may be further formed in the deceleration housing 30 to more effectively prevent the first flow path 34 from colliding with the front side wall of the braking housing 30 (or the rear side wall of the braking housing 40) have.

That is, the deceleration housing 30 is connected to the front of the pressure housing 20, and a cylinder chamber 31a corresponding to a rear portion of the cylinder chambers 31a and 31b is formed. A first deceleration housing 30a on which the first deceleration housing 30a is formed; A cylinder chamber 31b is formed between the first deceleration housing 30a and the braking housing 40 and corresponds to a front portion of the cylinder chambers 31a and 31b, And a second deceleration housing 30b having an inlet 34a formed at the rear of the first flow path 34 and a second flow path 34 formed at the front thereof with a discharge port 34b. A check valve 35 may be provided between the inlet port 34a and the outlet port 34b for allowing the pressure to flow only from the inlet port 34a toward the outlet port 34b.

3, the first deceleration housing 30a and the second deceleration housing 30b are continuously connected to the front of the pressure housing 20, and the first deceleration housing 30a and the second deceleration housing 30b are connected to each other, The first flow path 32 is formed in the first reduction housing 30a and the second flow path 34 is formed in the second reduction housing 30b.

The first deceleration housing 30a is connected to the front of the pressure housing 20 as described in the detailed description of the deceleration housing 30 and corresponds to a rear portion of the cylinder chambers 31a and 31b And the first flow path 32 is formed. A detailed description of the first flow path 32 will be omitted in the above description.

The cylinder chamber 31a formed in the first reduction housing 30a corresponds to a rear portion of the cylinder chambers 31a and 31b of the deceleration housing 30 described above.

The second deceleration housing 30b is connected between the first deceleration housing 30a and the braking housing 40 and includes a cylinder chamber 31b corresponding to a front portion of the cylinder chambers 31a and 31b, A second flow path 34 is formed in the rear of the cylinder chamber 31b and an inlet 34a is formed in the cylinder chamber 31b and a discharge port 34b is formed in the front of the cylinder chamber 31b. (30b) is connected to the front side of the first reduction housing (30a).

That is, the cylinder chamber 31b of the second deceleration housing 30b is formed in a part of the front side of the cylinder chambers 31a and 31b of the deceleration housing 30, and the second flow path 34 is formed, The effect of increasing the decelerating force for decelerating the rod 10 by the same principle as the first flow path 32 and preventing the front end of the head 11 from colliding against the front side wall of the decelerating housing 30. [

3, the inlet 34a is formed on the rear side of the cylinder chamber 31b of the second reduction housing 30b, and the outlet 34a communicated with the inlet 34a 34b are formed on the front side of the cylinder chamber 31b of the second reduction housing 30b. A check valve 35 is provided between the inlet port 34a and the outlet port 34b of the second flow path 34 to allow the pressure to flow only from the inlet port 34a toward the outlet port 34b, The air flowing in the flow path 34 can always flow only from the inlet port 34a toward the outlet port 34b so that the position of the head 11 at the position where it closes the inlet port 34a of the second flow path 34 The air in the discharge port 34b of the check valve 35 and the second flow path 34 and the air in the cylinder chamber of the second reduction housing 30b corresponding to the front of the head 11 31b so that the front end of the head 11 does not hit the front side wall of the deceleration housing 30. As a result,

That is, when the rod 10 moves forward and the head 11 provided on the rod 10 is moved to the cylinder chamber 21 of the pressure housing 20 and the cylinder chamber 31a of the first deceleration housing 30a The head 11 is positioned in the cylinder chamber 31b of the second deceleration housing 30b and the air in the cylinder chamber 31b in front of the forward moving head 11 Is continuously compressed toward the front of the inlet 34a of the second flow path 34 and the cylinder chamber 31b of the second reduction housing 30b.

At this time, the compressed air at the front side of the cylinder chamber 31b of the second deceleration housing 30b flows into the discharge port 34b of the second flow path 34 and flows into the second flow path 34 The check valve 35 blocks the air flowing back from the discharge port 34b of the second flow path 34 in the direction of the inlet port 34a so that the check valve 35 and the second A part of the flow path 34 and the air contained in the cylinder chamber 31b of the second deceleration housing 30b are compressed to a higher pressure to apply a decelerating force to the rod 10, Thereby preventing collision between the front side walls of the deceleration housing 30b.

When the head 11 continuously advances to block the inlet 3 of the second flow path 34 formed in the cylinder chamber 31b of the second reduction housing 30b or to the front of the inlet, The inlet of the second flow path 34 is influenced by the internal pressure of the cylinder chamber 31a of the first reduction housing 30a and the cylinder chamber 31a of the first reduction housing 30a, I) the internal pressure of the cylinder chamber 31a of the first decelerating housing 30a is equal to or higher than the pressure of the check valve 35 and the cylinder chamber 21 of the pressurizing housing 20, The internal air of the cylinder chamber 31a of the first deceleration housing 30a flows through the check valve 35 to the second flow 34a of the first reduction housing 30a, A portion of the second flow path 34 formed in front of the check valve 35 and the head 11 and a portion of the cylinder chamber 31b of the second deceleration housing 30b, Ii) the pressure formed between the check valve 35 and the discharge port 34b of the second flow path 34 is higher than the internal pressure of the cylinder chamber 31a of the first reduction housing 30a The check valve 35 closes the air flowing backward from the discharge port 34b of the second flow path 34 toward the inlet port 34a so that the check valve 35 and the front end of the head 11 And the pressure in the cylinder chamber 31b of the second reduction housing 30b is not lost.

In addition, the second flow paths 34 are formed in a plurality of shapes as shown in FIG. 5, and each of the second flow paths 34 is radially formed around the cylinder chamber 31b of the second reduction housing 30b. It is preferable that the pressure in the cylinder chamber 31b of the cylinder head 30b can be uniformly flowed to the front of the head 11. The discharge port 34b of the plurality of second flow paths 34 is also radially formed around the cylinder chamber 31b of the second reduction housing 30b so that the cylinder 34b of the second reduction housing 30b, It is preferable that a uniform pressure is formed in front of the head 11 which moves forward toward the front of the chamber 31b.

When the deceleration housing 30 includes the first deceleration housing 30a and the second deceleration housing 30b as described above, the discharge port 34b of the second flow channel 34 is connected to the second flow The discharge port 34b of the second flow path 34 is formed in the cylinder chamber 31b on the front side of the inlet 34a of the second reduction housing 30b Of the cylinder chamber 31b of the cylinder chamber 31b.

That is, since the discharge port 34b of the second flow path 34 having the above-described structure is formed on the side surface of the distal end of the second reduction housing 30b in front of the cylinder chamber 31b, Even if the front end of the head 11 provided is moved forward to the end adjacent to the front end of the cylinder chamber 31b of the second reduction housing 30b, the pressure formed in the second flow path 34 is continuously supplied to the second reduction housing 30b Can be applied to the cylinder chamber 31b of the cylinder chamber 31b.

When the decelerating housing 30 includes the first decelerator housing 30a and the second decelerator housing 30b as described above, the normally discharging passage 33 is connected to the outlet of the first flow path 32, May be formed in a predetermined portion of the cylinder chamber 31a of the first deceleration housing 30a or the cylinder chamber 31b of the second deceleration housing 30b corresponding to the front of the first deceleration housing 32b, Is formed between the inlet port (34a) of the second flow path (34) formed in the second deceleration housing (30b) and the outlet port (34b).

That is, the normally-discharge path 33 of the above-described configuration is arranged so that the head 11 passes through the inlet 34a of the second flow path 34 and flows into a certain portion of the cylinder chamber 31b of the second reduction housing 30b The internal space between the cylinder chamber 31b of the second deceleration housing 30b and the front of the head 11 between the check valve 35 and the outlet 34b of the second flow path 34 in the state of being positioned, It is possible to realize the effect of preventing the exhaust gas from being discharged to the normal discharge path (33).

At this time, in this state, the head 11 provided in the rod 10 blocks the normally discharging path 33 or the front end of the head 11 is in the cylinder chamber 31b of the second decelerating housing 30b, Even if the cylinder chamber 31b of the second deceleration housing 30b and the front end of the head 11 are moved between the check valve 35 and the outlet 34b of the second flow path 34, Thereby increasing the deceleration force of the rod 10 provided with the head 11 and increasing the speed of rotation of the cylinder 11 in the cylinder chamber 31b of the head 11 and the second deceleration housing 30b, It is possible to realize the effect of preventing collision between the front wheels.

When the deceleration housing 30 includes the first deceleration housing 30a and the second deceleration housing 30b as described above, the discharge port 34b of the second flow path 34 and the check valve Pressure pressurizing pipe 36 to which a pressure can be supplied from the outside can be connected between the pressurizing pipes 36 and 35. [

That is, the low-pressure pressurizing pipe 36 having the above-described configuration supplies air having a constant pressure from the outside to the second flow path 34 to move forward in the cylinder chamber 31b of the second reduction housing 30b The completed head 11 can be moved backward to return the previously moved rod 10 back to its original position.

At this time, it is preferable that the air can flow only in the direction of the second flow path 34 from the low pressure pressurizing pipe 36 between the low pressure pressurizing pipe 36 and the second flow path 34 , The present invention further comprises a check valve 35 (not shown) between the low pressure pressurizing pipe 36 and the second flow path 34, and the check valve 35 (2) Pressure pressurizing line 36 to the low-pressure pressurizing line 36 so that the air can flow only from the low-pressure pressurizing line 36 to the second flow path 34 without flowing out of the pressure.

The pressure of the air supplied to the second flow path 34 through the low pressure pressurizing pipe 36 is smaller than the pressure supplied to the cylinder chamber 21 of the pressure housing 20, If the head 11 contained in the cylinder chamber 31b of the pressure chamber 30b has a pressure such that the head 11 can move backward together with the rod 10 and return to the rear of the cylinder chamber 21 of the pressure housing 20, As shown in FIG.

The braking housing 40 is connected to the front of the decelerating housing 30 and is connected to a hollow cylinder chamber 41 communicating with the cylinder chambers 31a and 31b of the decelerating housing 30, And a braking member (44) having a brake pad (42) capable of friction with the outer surface of the rod (10), wherein the pressure in the cylinder chamber (21) of the pressure housing (20) The rod 10 is grasped while the rod 10 is formed so as to be able to advance the rod 10 instantaneously, or the rod 10 moving instantaneously is allowed to advance after a certain distance and then stopped.

That is, the braking housing 40 is configured such that the cylinder chamber 41 of the braking housing 40 is connected to the cylinder chamber 21 of the pressure housing 20 and the cylinder chambers 31a and 31b of the deceleration housing 30, And is connected to the front side of the deceleration housing 30. The deceleration housing 30 is connected to the front side of the deceleration housing 30. The inner diameter of the cylinder chamber 41 of the braking housing 40 is configured to be larger than the outer diameter of the rod 10 so that the rod 10 moving forward can not interfere with the cylinder chamber 41 of the braking housing 40 .

The rod 10 is longer than the length of the cylinder chamber 21 of the pressure housing 20, the cylinder chambers 31a and 31b of the decelerating housing 30 and the cylinder chamber 41 of the braking housing 40 So that a part of the front end of the rod 10 is drawn out to the front of the cylinder chamber 41 of the braking housing 40 so as to be connected to a link guide of a known automobile pitching simulator or to be fastened to a weight body It will be self-evident.

The braking member 44 provided in the braking housing 40 is positioned in the cylinder chamber 41 of the braking housing 40 or outside of the braking housing 40, So that the outer surface of the rod 10 and the brake pad 42 can be interfered with each other to be rubbed or released from friction.

That is, the braking housing 40 may be configured in various forms to move the rod 10 back and forth by the cylinder chamber 41, and as the braking member 44 provided, A body in which a hollow cylinder chamber 41 is formed at the center in the longitudinal direction of the actuator, At least one lower brake pad (42) fixedly provided under the inner surface of the cylinder chamber (41); And an upper brake (not shown) provided on the upper side or the side of the inner surface of the cylinder chamber 41 so as to be able to move up and down in a direction perpendicular to the outer surface of the rod 10, A pad 42; And a braking member 44 which is fastened to one end of the body and is fastened to the end of the lifting rod 43 in which the upper brake pad 42 moves up and down in the direction of the cylinder chamber 41 .

That is, the body is in the form of a braking housing 40 and a hollow cylinder chamber 41 is formed at the center in the longitudinal direction of the actuator. The braking housing 40 is connected to the front of the deceleration housing 30 .

The lower brake pad 42 is provided in a fixed state below the inner surface of the cylinder chamber 41 and provides a frictional force to the lower portion of the rod 10 which is inserted into the cylinder chamber 41.

At this time, the lower brake pad 42 is normally operated only by the frictional force due to interference between the rod 10 and the lower brake pad 42 formed by the weight of the rod 10, but the upper brake pad 42 When a pressing force for friction is applied to the upper portion of the rod 10, a part of the pressing force acts between the lower brake pad 42 and the lower portion of the rod 10 to increase frictional force due to interference.

The friction surface of the lower brake pad 42 may protrude more toward the center of the cylinder chamber 41 than the lower surface of the inner surface of the cylinder chamber 41.

When the rod 10 has a quadrangular outer periphery and one of the vertexes is positioned lower and the rod 10 is recessed into the cylinder chamber 41 in the form of a rhombus, It is preferable that they are provided on both lower surfaces of the diamond-like cylinder chamber 41 so as to correspond to both lower surfaces of the rod 10.

The upper brake pad 42 is provided on the upper side or the side of the inner surface of the cylinder chamber 41 and can move up and down in a direction perpendicular to the outer surface of the rod 10 to frictionally contact the outer surface of the rod 10 The brake pad 42 has the same structure as that of the lower brake pad 42, but is provided so as to be movable up and down on the inner surface or the inner surface of the cylinder chamber 41.

The upper brake pad 42 is provided in the cylinder chamber 41 at a position corresponding to the upper or side of the rod 10 and is moved in the direction of the rod 10 if necessary to press the rod 10, (10).

Specifically, the upper brake pad 42 presses the top or side of the rod 10 to grasp the rod 10 before the rod 10 is advanced, or to stop the rod 10 being advanced, .

At this time, the braking member 44 is fastened to one side of the body and the upper brake pad 42 is fastened to the end of the lifting rod 43, which moves up and down in the direction of the cylinder chamber 41, For example.

That is, the braking member 44 is configured to provide a pressing force for stopping the rod 10, and one side of the braking member 44 is coupled to the body. The braking member 44 lifts the lifting rod 43 by hydraulic pressure or pressure, The upper brake pad 42 fastened to one side of the cylinder chamber 41 is moved up and down in the cylinder chamber 41.

The braking member 44 and the upper brake pad 42 may be configured in various numbers according to the judgment of a person skilled in the art.

The operation of the actuator for crash test according to the preferred embodiment of the present invention will be described in detail with reference to FIGS. 7 to 15. FIG.

The present invention is characterized in that the cylinder chamber 21 of the pressure housing 20, the cylinder chamber 31a of the first decelerating housing 30a and the cylinder chamber 31b of the second decelerating housing 30b during the forward movement of the rod 10 7, the "D portion 50" of the cylinder chamber 21 of the pressure housing 20 and the " D portion 50 " of the cylinder chamber 31a of the first reduction housing 30a, F portion 52 "of the second flow path 34 communicating with the cylinder chamber 31b of the second reduction housing 30b and the" E portion 51 "of the first flow path 32 and the" F portion 52 " To obtain pressure change values of D, E and F in accordance with the forward movement (time) of the rod 10 as shown in Fig.

At this time, the pressure of the D portion 50 indicates the pressure state of the cylinder chamber 21 of the pressure housing 20, and the pressure of the E portion 51 is equal to the pressure of the cylinder chamber 31a of the first deceleration housing 30a The pressure of the F portion 52 indicates the pressure state of the first flow path 32 and the pressure in the cylinder chamber 31b of the second reduction housing 30b and the second flow path 34 34) between the discharge port 34b of the check valve 35 and the check valve 35).

7, the upper brake pad 42 positioned on the upper side of the cylinder chamber 41 of the braking housing 40 is moved to the front side of the rod 10 by the descent of the lifting rod 43 of the braking member 44 The outer surface is pressed so as to grip the rod 10 with the lower brake pad 42 so as not to move. Further, the pressure tank connected to the pressurizing pipe 22 is kept filled with a certain pressure (hereinafter referred to as a high pressure).

8, when the lifting rod 43 of the braking member 44 is lifted and lowered, a high-pressure pressure stored in the pressure tank is supplied to the cylinder chamber 21 of the pressure housing 20 through the pressure pipe 22, And the head 11 of the rod 10 which is inserted into the rear of the cylinder chamber 21 of the pressure housing 20 is instantaneously moved forwardly of the cylinder chamber 21 of the pressurizing housing 20 And as a result, the rod 10 connected to the head 11 is also moved forward.

At this time, the air that has been stored in the front side of the head 11 through the normally discharging path 33 formed between the inlet 34a and the outlet 34b of the second flow path 34 of the second deceleration housing 30b, So that the forward movement of the rod 10 is prevented from being impeded by the pressure of air contained in the front of the head 11. [

9A, when the rear end of the head 11 passes through the inlet 32a of the first flow path 32 of the first reduction housing 30a, the inlet 32a of the first flow path 32, A part of a high pressure portion for pressurizing the rear side of the head 11 flows through the discharge port 32b of the first flow path 32 toward the front of the head 11, A part of the high-pressure pressure introduced into the front side flows into the cylinder chamber 31a of the first reduction housing 30a, the inlet 34a of the second flow passage 34, the cylinder chamber 31b of the second reduction housing 30b, And flows into the discharge port 34b of the second flow path 34 to apply a primary deceleration to the head 11 on the front side of the head 11. [

At this time, a part of the high pressure of the cylinder chamber 31b of the second deceleration housing 30b is continuously discharged to the outside through the normal discharge passage 33. However, due to the forward movement of the head 11, The amount of air to be compressed in the cylinder chamber 31a of the housing 30a, the cylinder chamber 31b of the second deceleration housing 30b and the second flow path 34 is maintained at the outside The first deceleration with respect to the head 11 applied on the front side of the head 11 can be maintained.

The flow of the high pressure through the first flow path 32 toward the front side of the head 11 causes the front end of the head 11 to move forward as shown in FIG. ).

It is also confirmed that the pressure of the E part 51 and the F part 52 is increased when the first deceleration is formed with respect to the head 11 as in the G section 53 of FIG. ) And the F portion 52 mean a deceleration of the rod 10 due to deceleration of the head 11.

10A, the head 11 continuously moves forward by the high pressure of the cylinder chamber 21 of the pressure housing 20, so that the front end of the head 11 is moved to the first deceleration housing 30a, The pressure of the high pressure in the cylinder chamber 21 of the pressurizing housing 20 is not discharged to the discharge port 32b of the first flow path 32 while the discharge port 32b of the head 11 is closed, The pressure in the cylinder chamber 31a of the first reduction housing 30a, the second flow passage 34 and the cylinder chamber 31b of the second reduction housing 30b is continuously compressed.

10B, when the front end of the head 11 is advanced to the normally discharging path 33 and the normally discharging path 33 is closed, the cylinder 11 of the first decelerating housing 30a on the front side of the head 11, The pressure in the cylinder chamber 31b of the first flow path 31a, the second flow path 34 and the second deceleration housing 30b is more strongly compressed so that the secondary deceleration is applied to the head 11 on the front side of the head 11. [ .

It can be confirmed that the pressure of the E part 51 and the F part 52 is increased when the second deceleration is formed with respect to the head 11 as in the H section 54 of FIG. The pressure of the F portion 52 rapidly increases to confirm that the buffering (decelerating) function of the head 11 is maximized by the pressure inherent in the F portion 52.

In addition, if the pressure of the F portion 52 becomes equal to the forward movement power of the head 11 after the head 11 continuously advances in the state of FIG. 10B, the F portion of the H section 54 of FIG. 14 52, and the forward movement of the head 11 is stopped.

11A, since the maximum pressure value of the F portion 52 is greater than the sum of the forward movement power of the head 11 and the high pressure of the D portion 50, The front end of the head 11 moves backward so that the normally discharging path 33 is in an open state. At this time, the pressure of the F portion 52 is discharged to the outside through the constant discharge passage 33 formed in the cylinder chamber 31b of the second deceleration housing 30b, and the constant discharge passage 33 The pressure of the F portion 52 is decreased by the pressure exerted on the F portion 52 so that the pressure of the F portion 52 becomes smaller than the pressure of the D portion 50 like the I section 55 of Figure 14, The head 11 is moved forward again.

That is, the pressure of the F portion 52 in the state as shown in FIG. 11B is increased again to apply a buffering force to the head 11, so that the third deceleration with respect to the head 11 as in the J section 56 of FIG. . At this time, since the pressure of the F portion 52 is in a state in which a part of the pressure is reduced through the normally discharging path 33 after the second deceleration, the head 11 is further subjected to the second deceleration The rear end of the head 11 is advanced to the position advanced further than the usual discharge passage 33 and the normally discharging path 33 is opened .

At this time, the normal discharge passage 33 is located in the rear of the cylinder chamber 21 of the pressure housing 20, the cylinder chamber 31a of the first deceleration housing 30a, and the cylinder chamber 31b of the second deceleration housing 30b The pressure (residual pressure) inherent to the head 11 can be released to the outside and most of the pressure applied to the rear side of the head 11 can be released.

The braking pad 42 of the braking housing 40 is moved downward by the descent of the lifting cylinder of the braking member 44 while the first and second deceleration, The load 10 can be decelerated and stopped by rubbing against the outer surface of the rod 10 and the load 10 can be reduced by the first deceleration, the second deceleration, and the third deceleration without the deceleration of the rod 10 by the sake brake pad 42, Deceleration and stop of the motor 10 may be realized.

13, when the rod 10 is stopped, the head 11 of the rod 10 is positioned in the front of the cylinder chamber 31b of the second reduction housing 30b A person skilled in the art will be able to apply a pressure to the low pressure pressurized pipe 36 connected between the discharge port 34b of the second flow path 34 and the check valve 35 and to apply the pressure to the rod 10, To the rear side of the cylinder chamber (21) of the pressure housing (20).

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, but, on the contrary, It is possible to carry out various changes in the present invention.

10: load 11: head
20: pressure housing 21: cylinder chamber
22: pressure piping 30: deceleration housing
30a: first reduction housing 30b: second reduction housing
31a, 31b: cylinder chamber 32: first flow path
32a: Inlet port 32b: Outlet port
33: normal discharge path 34: second flow path
34a: Inlet port 34b: Outlet port
35: Check valve 36: Low pressure pressure piping
40: Braking housing 41: Cylinder chamber
42: Brake pad 43: Lift rod
44: breaking member 50: D portion
51: E part 52: F part
53: G section 54: H section
55: I section 56: J section

Claims (5)

A rod 10 having a length in the longitudinal direction of the actuator and having a head 11 at the rear;
A pressurizing housing 20 connected to a pressurizing pipe 22 to which a pressure is applied to the rear side and having a hollow cylinder chamber 21 formed therein in the longitudinal direction of the actuator to allow the rod 10 to be inserted from the rear side;
A middle portion of the rod 10 is inserted into hollow cylinder chambers 31a and 31b connected to the front of the pressure housing 20 and communicating with the cylinder chamber 21 of the pressure housing 20, A first flow path 32 formed with an inlet 32a at the rear of the cylinder chambers 31a and 31b and a discharge port 32b formed at the front thereof and a first flow path 32 communicating with the cylinder chambers 31a and 31b, A deceleration housing 30 having a passage 33 formed therein;
A front portion of the rod 10 is inserted into a hollow cylinder chamber 41 connected to the front of the decelerating housing 30 and communicated with the cylinder chambers 31a and 31b of the decelerating housing 30, And a braking member (40) having a braking member (44) having a brake pad (42) capable of friction with an outer surface of the braking member (10).
The method according to claim 1,
The deceleration housing (30)
A cylinder chamber 31a corresponding to a rear portion of the cylinder chambers 31a and 31b is formed in the front of the pressure housing 20 and a first deceleration housing 30a);
A cylinder chamber 31b is formed between the first deceleration housing 30a and the braking housing 40 and corresponds to a front portion of the cylinder chambers 31a and 31b, And a second deceleration housing 30b having an inlet 34a formed at a rear portion thereof and a second flow passage 34 formed at a front portion thereof with an outlet 34b,
Characterized in that a check valve (35) is provided between the inlet (34a) and the outlet (34b) of the second flow path (34) to flow pressure only in the direction of the outlet (34b) from the inlet (34a) Test actuator.
3. The method of claim 2,
The discharge port (34b) of the second flow path (34)
Is formed on the side surface of the front end of the cylinder chamber (31b) of the second deceleration housing (30b).
3. The method of claim 2,
The normal discharge path (33)
Is formed between an inlet (34a) and an outlet (34b) of the second flow path (34) formed in the second deceleration housing (30b).
3. The method of claim 2,
Between the discharge port 34b of the second flow path 34 and the check valve 35,
And a low pressure pressurizing pipe (36) to which a pressure can be supplied from outside can be connected.

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