JP6780122B2 - Impact test equipment - Google Patents

Description

The present invention relates to an impact test device for testing an impact when a test object such as a home appliance is dropped.

Conventionally, products such as home appliances and personal computers have been tested for damage due to impacts such as dropping during transportation and use. JIS C-60068-2-27 defines this test method. In this regulation, the magnitude, duration of action, number of tests, direction, etc. of the impact pulse are specified. Further, JIS Z 0119 defines an impact test method for confirming the impact strength of the product itself. This specification specifies how to apply the impact pulse to obtain the damage boundary curve of the product.

As a device for performing such an impact test, there is a device for measuring the impact when the test object is dropped from a predetermined height. However, in recent years, there has been a demand for an apparatus capable of performing an impact test in which a test object is dropped from a higher position.

Prior arts for this type of impact tester include, for example, a mounting table that is held at a predetermined height, a breaking bolt that is provided above the mounting table, and a cylinder that pulls the mounting table upward via a breaking bolt. , There is an impact test device including a compression spring that applies a downward force to the mounting table by being compressed by a cylinder, and a collision member provided below the mounting table (see, for example, Patent Document 1). In this impact test device, the mounting table is pulled upward by the cylinder against the force of the compression spring, and the force of the compression spring is released at once by the breaking of the breaking bolt to cause the mounting table to collide with the collision member. In this device, the force of the compression spring is used to perform an impact test from a position higher than the actual height.

Further, as another prior art, there is an impact test device including a mounting table held at a predetermined height position and a launching means for launching a colliding body provided below the mounting table upward (for example,). , Patent Document 2). This impact test device is provided with a breaking bolt that holds the colliding body at a predetermined height position and a compression spring that applies an ascending force to the colliding body. Then, the elastic energy of the compression spring is released at once by the breakage of the breaking bolt to accelerate the colliding body and cause it to collide with the mounting table. This device also uses the force of the compression spring to perform an impact test from a position higher than the actual height.

Japanese Patent Application Laid-Open No. 2012-127927 Japanese Patent Application Laid-Open No. 2000-249620

However, in both the impact test devices of Patent Document 1 and Patent Document 2 described above, the portion where the test object is installed is urged in a direction resisting the force of the compression spring, and is released at once by the breakage of the breaking bolt. The elastic energy of the compression spring causes the load portion to collide with the collision member. For this reason, both prior arts are very large impact testers that collide the test object with a large force that breaks the breaking bolt. Therefore, the installation location of the device is limited, and the test location of the test object is limited.

It is also conceivable that the impact table portion on which the test object is placed is accelerated by an air cylinder and dropped. However, in the case of an air cylinder, the device becomes large, and a lot of time and labor are required for maintenance of each sliding part. Moreover, the reproducibility of the impact test may deteriorate due to deterioration of the seal portion due to long-term use.

Therefore, an object of the present invention is to provide an impact test apparatus capable of forming an apparatus compactly and performing an impact test with high reproducibility.

In order to achieve this object, the present invention is an impact test apparatus for testing an impact when a test object is dropped, and an impact table portion on which the test object is placed and dropped, and the impact table portion. A guide portion that guides the impact table portion in the vertical direction, an elevating portion that lifts the impact table portion to a predetermined height along the guide portion, a holding portion that holds the impact table portion at a predetermined height of the guide portion, and the impact. The base portion having a collision portion arranged in the drop portion of the table portion, the sensor for detecting the impact when the impact table portion collides with the collision portion, and the impact table portion held by the holding portion are dropped. A control unit is provided, and the guide unit is arranged so as to guide the opposite positions of the impact table unit, and the base unit urges the impact table unit downward when the impact table unit is raised. A spring member that increases the falling speed of the impact table portion and a spring guide that suppresses the central portion of the spring member from flapping in the lateral direction are located close to the guide portion on the side of the collision portion. The spring guide is made of a resin material and has a spring insertion hole through which the spring member is inserted, and the spring insertion hole is connected to the spring member in a state where the spring member is inserted. A predetermined gap is formed between them, and is configured to suppress the fluttering of the spring member.

With this configuration, the impact table portion on which the test object is placed is lifted to a predetermined height by the elevating portion along the guide portion and held by the holding portion, so that the impact table portion is prepared at a position close to the guide portion of the base portion. It is held in a downwardly urged state by the spring member. Then, by opening the holding portion, the impact table portion is given the same drop speed as when dropped from a height higher than the actual height by gravity and the initial acceleration by the spring member, and the impact test is performed. Can be done. The impact at this time can be detected by a sensor. As a result, it is possible to compactly form an impact test device capable of performing an impact test from a height higher than the actual height while suppressing the height and the occupied area. In addition, the spring member allows an impact test with high reproducibility of the impact waveform.

Further, the base portion further provides a spring guide at a position close to the guide portion on the side of the collision portion. Since the spring guide has a spring insertion hole in which a predetermined gap is formed between the spring member and the spring member in the inserted state, the central portion of the spring member extending in the vertical direction is the collision portion. The spring guide can prevent flapping on the side. As a result, the spring member can be stably contracted when the impact table portion is dropped.

Further, since the spring guide is made of a resin material and the spring member is inserted into the spring insertion hole, noise can be suppressed and fluttering can be suppressed even if the spring member comes into contact with the spring guide of the resin material when the spring member contracts. it can.

Further, a plurality of each of the spring members may be arranged. With this configuration, a large drop speed can be obtained even if the impact table portion is dropped from a low height by the force of a plurality of spring members. Moreover, the arrangement space can be reduced by using a plurality of spring members. Moreover, the falling speed of the impact table portion can be changed by adjusting the number of spring members.

Further, the holding portion may be composed of a hydraulic holding portion that holds the impact table portion on the guide portion at a predetermined height. With this configuration, even if a downward urging force of the spring member is applied to the impact table portion raised to a predetermined height, the impact table portion is held by the guide portion by a hydraulic holding portion such as a hydraulic brake. Can be kept properly.

Further, a cover portion that covers the side of the spring member may be further provided. With this configuration, it is possible to suppress the noise generated in the spring member from leaking to the surroundings.

According to the present invention, since the falling speed of the impact table portion can be increased by the spring member, it is possible to reduce the height of the impact test apparatus and achieve compactness. In addition, the spring member makes it possible to perform an impact test with high reproducibility of the impact waveform.

FIG. 1 is a front view of an impact test device according to an embodiment of the present invention. FIG. 2A is a plan view of the impact test apparatus shown in FIG. 1, and FIG. 2B is a plan view of a spring guide. 3 (A) and 3 (B) are cross-sectional views showing a mounting portion of a spring member of the impact test apparatus shown in FIG. FIG. 4 is a cross-sectional view showing a holding portion of the impact table portion shown in FIG. FIG. 5 is a front view showing a portion of the collision portion shown in FIG. FIG. 6 is a front view of the impact test apparatus shown in FIG. 1 during the test. FIG. 7 is a side view of the impact test apparatus shown in FIG. 6 during the test. FIG. 8 is a front view of the impact test device from the state shown in FIG. 6 to the state immediately before the impact test.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following embodiment, the impact test device 1 for raising and lowering the impact table portion 20 on which the test object 80 is placed and dropped along the guide portions 30 arranged on the left and right will be described as an example. The concept of the vertical and horizontal directions in this specification and the documents of the claims shall be consistent with the concept of the vertical and horizontal directions in the state facing the impact test device 1 shown in FIG.

(Overall configuration of impact test equipment)
FIG. 1 is a front view of the impact test device according to the embodiment. FIG. 2A is a plan view of the impact test apparatus shown in FIG. 1, and FIG. 2B is a plan view of a spring guide. As shown in FIG. 1, in the impact test device 1 of this embodiment, the base portion 11 is provided above the base plate 10 fixed at the installation position. The base portion 11 is supported by the base plate 10 by air springs 12 provided at front and rear positions. By supporting the base portion 11 with the air spring 12, the impact during the impact test is suppressed from being transmitted to the base plate 10. A collision portion 13 is provided on the upper portion of the base portion 11. Above the collision portion 13, an impact table portion 20 for dropping from above toward the collision portion 13 is provided.

The impact table portion 20 is guided in the vertical direction along a guide portion 30 provided upward from the base portion 11. The guide portion 30 has a guide shaft 31 that is arranged so as to guide the positions facing each other across the central portion of the impact table portion 20. The base portion 11 is provided with an elevating portion 35 that lifts the impact table portion 20 to a predetermined height along the guide shaft 31. The impact table portion 20 is lifted by the elevating portion 35 along the guide portion 30 to a predetermined height, dropped from the predetermined height, and collided with the collision portion 13 (FIGS. 6-8). The elevating part 35 is composed of an air cylinder 36.

As shown in FIG. 2A, the impact table portion 20 has a mounting portion 21 on which the test object 80 is placed in the central portion. Guide blocks 22 having guide holes 23 through which the guide shaft 31 is inserted are provided on the left and right opposite side portions of the mounting portion 21. The impact table portion 20 is moved up and down by being guided by a guide shaft 31 with a guide hole 23 at a position facing the mounting portion 21 in the central portion. A holding portion 40 for holding the impact table portion 20 raised along the guide shaft 31 at a predetermined height is provided in the portion of the guide hole 23.

Then, spring members 50 are provided on both side portions of the guide block 22 to urge the impact table portion 20 downward when the impact table portion 20 rises to increase the falling speed of the impact table portion 20. A plurality of spring members 50 are arranged side by side between the spring mounting portion 24 projecting laterally from the guide block 22 of the impact table portion 20 and the spring fixing portion 16 provided on the base portion 11. The spring member 50 is composed of a tension spring having a predetermined spring constant. In this example, four spring members 50 are arranged side by side on both sides of the impact table portion 20. The spring member 50 is arranged close to the guide portion 30.

Further, the base portion 11 is provided with a spring guide 55 for suppressing the spring member 50 from flapping. The spring guide 55 is a block body that projects laterally from the base portion 11, and is made of a resin material or the like. The spring guide 55 is provided on the side of the collision portion 13 provided on the base portion 11. The upper end of the spring guide 55 is located below the upper end of the collision portion 13.

As shown in FIG. 2B, the spring guide 55 is provided with a spring insertion hole 56 that penetrates in the vertical direction at the position where the spring member 50 is arranged at the same interval as the parallel arrangement interval of the spring member 50. It is a tubular member. The spring guide 55 of this embodiment is a cylindrical member having a vertically long rectangular shape in outer shape and provided with four spring insertion holes 56 in the vertical direction. The spring insertion hole 56 has a diameter larger than the outer diameter of the spring member 50, and a predetermined gap S is formed between the spring member 50 and the outer circumference of the spring member 50 in a state where the spring member 50 is inserted. The gap S can be a gap S corresponding to the outer diameter of the spring member 50, and can be, for example, about 3 mm or less. The spring guide 55 prevents the central portion of the spring member 50 from flapping in the lateral direction. If the spring guide 55 is made of a resin material, it is possible to suppress the fluttering of the spring member 50 while suppressing the noise when the spring member 50 comes into contact with the spring guide 55.

Further, as shown in FIG. 2A, the impact table unit 20 is provided with a sensor 26 that detects an impact when the impact table unit 20 collides with the collision unit 13. As the sensor 26, an acceleration sensor can be used. Further, the amount of the impact table portion 20 raised by the air cylinder 36 can be detected by the stroke sensor 37 provided between the impact table portion 20 and the base portion 11. The stroke sensor 37 detects the amount of rise of the impact table portion 20 by the amount of movement along the detection shaft 38 provided parallel to the guide shaft 31 (FIG. 7).

Further, in this embodiment, a cover portion 60 that covers the side of the spring member 50 is further provided on the side of the guide portion 30. The cover portion 60 of this embodiment is a cover material 61 that covers the periphery of the impact test device 1. The cover material 61 can be a resin cover material that covers the sides of the spring member 50. By providing the cover material 61, it is possible to take soundproofing measures for suppressing the noise generated in the spring member 50 from leaking to the surroundings.

Further, the impact test device 1 has a control for raising and holding the impact table unit 20 to a predetermined height, a control for dropping the impact table unit 20, a control for displaying the detection result of the impact generated on the impact table unit 20, and the like. A control unit 70 is provided. The control unit 70 includes a processor, a volatile memory, a non-volatile memory, an I / O interface, and the like. The control unit 70 includes an operation unit, a storage unit, an output unit, an input unit, and the like. The output unit and the input unit are realized by an I / O interface. The storage unit is realized by a volatile memory and a non-volatile memory. By the operation in the operation unit, the processor performs arithmetic processing using the volatile memory based on the program stored in the non-volatile memory, and each unit is controlled.

(Peripheral configuration of impact table)
3 (A) and 3 (B) are cross-sectional views showing a mounting portion of the spring member 50 of the impact test device 1 shown in FIG. FIG. 4 is a cross-sectional view showing a holding portion 40 of the impact table portion 20 shown in FIG. FIG. 5 is a front view showing a portion of the collision portion 13 shown in FIG.

As shown in FIG. 3A, the upper end of the spring member 50 is attached to the spring mounting portion 24 projecting laterally from the guide block 22 of the impact table portion 20. At the upper end of the spring member 50, a seat portion 51 and a mounting bolt 52 projecting upward are provided. The upper end of the spring member 50 is inserted into a bush 27 provided in the insertion hole 24a provided in the spring mounting portion 24 with a mounting bolt 52, and is fixed to the spring mounting portion 24 with a fixing nut 25. The seat portion 51 can be realized, for example, by attaching a screwing top to the end of the spring member 50. The mounting bolt 52 can be realized by standing it on the screwing top.

As shown in FIG. 3B, a seat portion 53 and a mounting bolt 54 projecting downward are provided at the lower end of the spring member 50. At the lower end of the spring member 50, a mounting bolt 54 is inserted into an insertion hole 16a of the spring fixing portion 16 provided on the side of the base portion 11, and is fixed to the spring fixing portion 16 with a fixing nut 17. This seat portion 53 can also be realized, for example, by attaching a screwing top to the end portion of the spring member 50. The mounting bolt 54 can be erected on the screwing top.

Further, as shown in FIG. 4, the holding portion 40 provided in the impact table portion 20 of this embodiment is a hydraulic brake 41 which is a hydraulic holding portion for holding the impact table portion 20 on the guide shaft 31 at a predetermined height. ing. The guide hole 23 of the impact table portion 20 is provided with a brake pad 42 that projects from the periphery toward the center. The portion of the brake pad 42 in contact with the guide shaft 31 is substantially semicircular. A seal portion 43 is provided on the outer peripheral side of the brake pad 42. A pressure oil chamber 44 is provided on the outer peripheral side of the seal portion 43. Pressure oil is supplied to the pressure oil chamber 44 from a pressure oil supply unit 45 connected to a pressure oil supply source (not shown). By supplying the pressure oil to the pressure oil chamber 44, the brake pad 42 presses the guide shaft 31 and can hold the impact table portion 20 at a predetermined position of the guide shaft 31. By using the hydraulic brake 41 as the holding portion 40, the impact table portion 20 raised against the urging force of the spring member 50 can be held at a predetermined position.

Further, as shown in FIG. 5, the collision portion 13 provided in the falling portion of the impact table portion 20 is provided with a shock absorber 14 in the portion where the impact table portion 20 collides. The shock absorber 14 is provided inside the tubular body 15 provided on the upper portion of the base portion 11. The cushioning body 14 is made of an elastic material such as rubber or plastic. The spring constant of the shock absorber 14 can be changed by changing the effective protrusion amount T from the tubular body 15. This buffer 14 is an example.

(Explanation of operation of impact test equipment)
FIG. 6 is a front view of the impact test device 1 shown in FIG. 1 during the test. FIG. 7 is a side view of the impact test device 1 during the test shown in FIG. FIG. 8 is a front view of the impact test device 1 from the state shown in FIG. 6 to the state immediately before the impact test. The operation of the impact test by the impact test device 1 will be described below.

First, the test object 80 is placed on the mounting unit 21 of the impact table unit 20, and the test conditions (drop height) are input in the control unit 70. The drop height (the height from the upper surface of the shock absorber 14 of the collision portion 13 to the lower surface of the impact table portion 20) in the impact test device 1 is the peak acceleration (designated) when the initial acceleration is given in advance by the spring member 50. By obtaining the correspondence between the impact acceleration) and the drop height, it is possible to input an appropriate drop height at which a desired peak acceleration can be obtained.

Then, the standby switch (not shown) is pressed. As a result, as shown in FIGS. 6 and 7, the air cylinder 36 is extended and the impact table portion 20 is raised along the guide shaft 31. At this time, the impact table portion 20 is raised against the urging force of the plurality of spring members 50. When the impact table portion 20 rises to a predetermined height, it is detected by the stroke sensor 37. As a result, the extension of the air cylinder 36 is stopped. Then, the impact table portion 20 is held at a predetermined position of the guide shaft 31 by the hydraulic brake 41 (holding portion 40) (FIG. 4).

After that, as shown in FIG. 8, the air cylinder 36 is lowered. This state is the state immediately before the impact test, and the impact table portion 20 is held by the hydraulic brake 41 while having the height energy held at a predetermined height and the downward urging force by the spring member 50. Has been done. Then, when the drop switch (not shown) is pressed in the control unit 70, the hydraulic brake 41 is released. As a result, the impact table portion 20 is dropped downward by its own weight and the urging force of the spring member 50 to collide with the collision portion 13. At the time of this collision, a designated impact acceleration is generated by the height energy of the impact table portion 20 and the downward urging force of the spring member 50. After the impact table portion 20 collides with the collision portion 13, the brake pad 42 of the hydraulic brake 41 may be brought into contact with the guide shaft 31 to prevent the impact table portion 20 from rebounding.

Then, the impact generated by the collision is measured by the sensor 26 and input to the control unit 70. When an acceleration sensor is used as the sensor 26, the acceleration on the impact table portion 20 is measured by the sensor 26. The measured acceleration of the drop impact test is analyzed and quantified by, for example, an acceleration measurement analysis system (not shown). As a result, an impact pulse can be obtained. The impact pulse can be displayed, for example, by equipping the control unit 70 with a monitor. As the analysis system, a system suitable for the type of the sensor 26 and the like may be adopted.

(Effect of impact test equipment)
As described above, according to the impact test device 1 described above, the impact table portion 20 on which the test object 80 is placed is lifted to a predetermined height by the elevating portion 35 along the guide portion 30 and held by the hydraulic brake 41. The impact table portion 20 can be appropriately held in a downwardly urged state by the spring member 50 provided on the base portion 11. That is, since the fixed position of the impact table portion 20 is held by the hydraulic brake 41, even when the downward urging force of the spring member 50 acts on the impact table portion 20 raised to a predetermined height, the impact table portion 20 is hydraulically pressed. The held state can be properly maintained.

Then, by releasing the hydraulic brake 41, the impact table portion 20 is given the same drop speed as when the impact table portion 20 is dropped from a height higher than the actual height, and the impact table portion 20 collides with the collision portion 13. An impact test can be performed by detecting the impact at the time with the sensor 26.

As described above, according to the impact test apparatus 1, the impact test can be performed by giving the test object 80 a speed of dropping from a position higher than the actual height, so that the impact test apparatus 1 is high. It is possible to suppress this and make it compact. Further, by adopting the spring member 50 as a configuration for applying a downward urging force to the impact table portion 20, it is possible to suppress the occupied area of the impact test device 1 and perform an impact test with high reproducibility of the impact waveform. It will be possible.

Moreover, by using a plurality of spring members 50, the number of spring members 50 can be adjusted to change the falling speed of the impact table portion 20. For example, in the above embodiment, four spring members 50 are provided on both sides of the impact table portion 20, so that the spring force acting on the impact table portion 20 is reduced by, for example, three spring members each. Can be done easily. The number of spring members 50 can be adjusted as needed. Further, by arranging the spring member 50 along the guide portion 30, maintenance of the spring member 50 can be easily performed.

Further, as described above, since the base portion 11 is provided with the spring guide 55 that guides the intermediate portion of the spring member 50 on the side of the collision portion 13, the center of the spring member 50 that contracts when the impact test is performed. It is possible to prevent the part from fluttering. As a result, the spring member 50 can be stably contracted when the impact table portion 20 is dropped.

(Modification example)
In the above-described embodiment, an example in which the impact table portion 20 is guided by the two guide shafts 31 has been described, but the configuration of the guide portion 30 is not limited to the above-described embodiment. For example, the same can be performed with an impact test device having a configuration in which the impact table portion 20 is guided by four guide shafts 31.

Further, the number and arrangement of the spring members 50 in the above-described embodiment are shown as an example, and the present invention can be carried out with different numbers of spring members 50, and various configurations are provided as long as the gist of the present invention is not impaired. It may be changed, and the present invention is not limited to the above-described embodiment.

1 Impact test device 13 Collision part 16 Spring fixing part 20 Impact table part 21 Mounting part 22 Guide block 24 Spring mounting part 26 Sensor 30 Guide part 31 Guide shaft 35 Lifting part 36 Air cylinder 40 Holding part 41 Hydraulic brake 50 Spring member 55 Spring guide 60 Cover 70 Control 80 Test object
S gap

Claims (4)

An impact test device that tests the impact when a test object is dropped.
An impact table on which the test object is placed and dropped, and
A guide unit that guides the impact table unit in the vertical direction and
An elevating part that lifts the impact table part to a predetermined height along the guide part,
A holding portion that holds the impact table portion at a predetermined height of the guide portion, and a holding portion.
A base portion having a collision portion arranged in a falling portion of the impact table portion, and a base portion.
A sensor that detects the impact when the impact table unit collides with the collision unit, and
A control unit for dropping the impact table unit held by the holding unit is provided.
The guide portions are arranged so as to guide the facing positions of the impact table portions.
The base portion has a spring member that urges the impact table portion downward to increase the falling speed of the impact table portion when the impact table portion rises, and a central portion of the spring member that flutters in the lateral direction. A spring guide for restraining is further provided at a position close to the guide portion on the side of the collision portion.
The spring guide is made of a resin material and has a spring insertion hole through which the spring member is inserted.
The spring insertion hole is configured such that a predetermined gap is formed between the spring member and the spring member in a state where the spring member is inserted, and the fluttering of the spring member is suppressed.
Impact test equipment characterized by this. A plurality of each of the spring members are arranged.
The impact test apparatus according to claim 1. The holding portion is composed of a hydraulic holding portion that holds the impact table portion on the guide portion at a predetermined height.
The impact test apparatus according to claim 1 or 2. A cover portion that covers the side of the spring member is further provided.
The impact test apparatus according to any one of claims 1, 2 and 5.

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