KR101199255B1 - A testing apparatus for measuring the strenghth of cabinet - Google Patents

Abstract

The present invention is a test device that can measure the rigidity of the cabinet structure by adding a load in various directions desired by the user is equipped with an actuator fixing device that can rotate, move up, down, left and right, more specifically, the cabinet in the actual use environment The present invention relates to a test apparatus capable of measuring stiffness by simulating the same various load environments, and a main configuration thereof is a bottom plate 130 and a bottom frame 120 rotatably installed on the bottom plate 130. ), A pair of vertical frames 110 installed on the lower frame 120 in parallel in a vertical manner, and a load adding device 10 installed on the vertical frames 110 so as to be installed left, right, up, and rotatable. And, the vertical frame 110, characterized in that it comprises a top frame 100 for fixing the top

Description

Test device for measuring cabinet rigidity {A TESTING APPARATUS FOR MEASURING THE STRENGHTH OF CABINET}

The present invention is a test device that can measure the rigidity of the cabinet structure by adding a load in various directions desired by the user is equipped with an actuator fixing device that can rotate, move up, down, left and right, more specifically, the cabinet in the actual use environment The present invention relates to a test apparatus capable of measuring stiffness by simulating the same various load environments.

In the case of household appliances such as refrigerators and washing machines, problems such as vibration and step may occur due to deformation and rigidity of the entire frame (cabinet) constituting the product when used for a long time. This problem causes noise during operation of the product, and especially in the case of the refrigerator, as cooling air leaks to the outside due to the stepped door, cooling performance is lowered, leading to reduced energy efficiency and consumer complaints.

Therefore, the manufacturer treats the optimization of the rigidity of the cabinet structure and the insertion of reinforcement as one of the important design factors when developing a new model in order to minimize the problems caused by the degradation of the rigidity of the cabinet structure and major components.

Therefore, the technology for measuring the rigidity of the cabinet structure is essential for the optimal design of the cabinet structure, such as a refrigerator, a washing machine.

As a tester capable of measuring the stiffness of structural and product elements such as a conventional cabinet or cabinet components, hydraulic universal testing machines of various companies have already been widely commercialized, but the price per tester is hundreds of millions of units. Because of the load generated by operating the actuator there is a disadvantage that the cost of maintaining and repairing the tester due to the auxiliary equipment such as motors, pumps.

When the hydraulic universal testing machine is used to make a separate jig, the rigidity test of a small product element can be easily performed, but the size and complexity of the structure, and the rigidity of the cabinet structure with various load application directions are very difficult to evaluate. In addition, in order to develop a new model cabinet or insert reinforcement into the cabinet structure, it is necessary to evaluate the rigidity in various load directions that the cabinet receives in a practical use environment. Applicability is very poor because it can be.

The present invention is to solve the problems with the conventional hydraulic universal testing machine as described above and to develop a test apparatus that can evaluate the rigidity of the cabinet, such as a refrigerator, a washing machine, by simulating the same load that the cabinet is subjected to in actual use environment It is an object of the present invention to provide a test apparatus that enables the application of loads of the same direction and size to the cabinet so that the rigidity of the direction can be measured.

The main constitution of the present invention for achieving the object of the present invention, in the test apparatus for measuring the rigidity of the cabinet structure of the test apparatus for evaluating the rigidity of the mechanical structure, the bottom plate, A lower frame installed on the bottom plate, at least one pair of vertical frames installed vertically on the lower frame, and a load adding device installed on the vertical frame so as to be installed left, right, up and down, and rotatable; It is configured to include a top frame for fixing the top to the vertical frame.

In addition, the lower frame is provided with a restraint device, the lower frame around the restraint device is rotatably installed on the bottom plate.

Fixtures are installed at both ends of the lower frame, and the vertical frame is installed perpendicular to the fixture.

In particular, the load-adding device is a vertical block respectively installed on both sides of the pair of vertical frames, a horizontal frame connecting horizontally between the vertical blocks installed on each vertical frame, and a movable block fitted to be fixed to the horizontal frame And a restraining device installed to be fixed to the moving block, and a round bar fixed to the restraining device.

The vertical block is formed with a cutout and a fastening hole capable of fastening the bolt, so that the vertical block is fixed to the vertical frame after the positional movement.

The constraining device is formed with a cutout to configure a round bar to be fitted, and a bolt fastening hole is formed in the constraining device, and is fixed by bolt fastening after moving the upper and lower positions of the round bar.

The fixing piece is coupled to an outer surface of the outer side of the movable block opposite to the restraining device so that the movable block is fixed on the horizontal frame after the positional movement in the horizontal direction of the horizontal frame.

An end of the restraint device is threaded to penetrate the moving block, and the end of the restraint device is coupled with a fixing piece disposed on an outer surface of the outer side of the moving block opposite to the restraining device.

Other features and configurations of the present invention described above will be further described below.

According to the device according to the present invention, the cabinet structure applied to the home appliance is sufficient to prevent structural deformation in the tester frame while the user applies the load because the working load in the actual use environment does not exceed 100 kg. It has rigidity and implements a frame and device that can rotate, move left and right, and move the actuator in order to add load to the cabinet structure in various directions. Easy to evaluate

In addition, it is possible to easily move with a small force without the need for a separate complicated equipment to rotate and move the actuator for loading, and the tester frame will be completely constrained with the bottom plate 130 during the test in the set load direction. It is possible to minimize vibration and measurement errors that may occur during the test.

In addition, it is necessary to measure the rigidity in various load directions due to the nature of the load conditions received in the environment in which the cabinet is actually used. In the case of using the test apparatus according to the present invention, it is necessary to manufacture individual jigs for each direction in order to test the cabinet rigidity measurement. It is possible to measure the stiffness in various directions using a single load applying device.

In addition, by using the test apparatus for measuring the rigidity of the cabinet according to the present invention, it is possible to evaluate the rigidity of the cabinet structure in product development stages such as refrigerators and washing machines, thereby requiring design modification and rigidity verification of the newly developed cabinet model. It is expected to decrease.

This will shorten the shipping period of the new model, and unnecessary economic reinforcement will not be used, so the economic effect is expected.

In addition, as quantitative evaluation of the stiffness-related factors of the cabinet structure is possible, it is expected that the optimal design of the cabinet structure to meet the required stiffness will be possible.

In addition, it is expected that the test evaluation agency that performs the cabinet stiffness measurement test of the product can be used to measure the cabinet stiffness by applying the tester according to the present invention, which minimizes the economic problems and environmental pollutants occurring in the existing hydraulic tester.

1 is an overall perspective view of a test apparatus according to an embodiment of the present invention.
Figure 2 is a view showing a test apparatus bottom frame fixed to the bottom plate.
3 is a view showing a fixing device for mounting the load-applying device capable of self-rotation and vertical movement.
4 is a view showing the back side of FIG. 3 with respect to a fixing device for mounting a load applying device.
Fig. 5 is a perspective view showing various installation displacements of the frame rotation and the load adding device in the device according to one embodiment of the present invention.
6 shows a test example using the apparatus according to one embodiment of the present invention.

In order to achieve the above object, the test apparatus for measuring the rigidity of the cabinet according to the present invention is configured to simulate the various load environments that the cabinet receives in an actual use environment and to add loads in various directions.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 shows a configuration of an entire test apparatus according to an embodiment of the present invention.

As shown, the test apparatus according to an embodiment of the present invention is the bottom frame 120 is fixed to the bottom plate 130 formed to be placed flat on the floor to be fixed without shaking, the bottom plate 130 and The lower frame 120 is tightly coupled by the restraining device 140 to be fixed without moving in contact with each other.

Fasteners 160 are integrally formed on the left and right sides of the upper surface of the lower frame 120 fixed to the bottom plate 130 so that the vertical frame 110 is inserted into the fasteners 160. As such, the load adding device 10 is installed between the vertical frame 110 and the fixed frame, and the upper frame 100 is installed on the top of the vertical frame 110 so that the vertical frame 110 is not twisted or bent. Are combined.

The load adding device 10 is configured to be vertically adjustable while vertically moving along a pair of vertical frame (110).

The restraint device 140 for fixing the lower frame 120 is fastened to the lower frame 120, as shown in FIG. The restraining device 140 has a structure in which a plurality of bolts 150 are coupled to each other.

When the bolt 150 fastened to the restraint device 140 is slightly released, the restraint state between the bottom plate 130 and the bottom frame 120 may be released to rotate the bottom frame 120. Then, the load adding device built on the lower frame 120 with the restraint device 140 as the center of the shaft may rotate the structure including the device 10. Thus, the tester can rotate the device to the desired position and fix it before use.

3 is a view for explaining the left and right, up and down movement operation of the load applying device 10, and FIG. 4 is a perspective view of FIG.

As shown, the load applying device 10 is connected via an annular rod 240 capable of supporting tensile and compressive loads applied to the cabinet structure under test, and the annular rod 240 connects the incision 228. It is fixed to the formed restraint device 220. At this time, the round bar 240 may be fixed by the surface pressure generated through the bolt fastening hole 270 that is processed in the restraining device 220. Round bar 240 may be made of a shape other than the round bar of course.

In particular, when the user wants to fix the desired position can be fixed at the desired position by bolting the position of the load-applying device 10.

The end of the restraining device 220 for fastening the load applying device 10 is processed in the form of a screw of a bolt, and is configured to be penetrated by the restraining piece 200 through the moving block 210. The moving block 210 can move left and right on the horizontal frame 250, and the restraining device 220 is rotatable on the moving block 210. Thus, after moving the moving block 210 to the desired position and tightened by the restraining piece 200 is fixed at that position.

In addition, by rotating the restraint device 220 at a desired angle on the movable block 210 and tightening the restraint device 200, the restraint device 220 may be fixed at a desired angle.

And both ends of the horizontal frame 250 is provided with a vertical block 230, the vertical block 230 is installed freely up and down in the vertical frame 110. That is, after the vertical block 230 is moved to a desired height, the bolt is fixed through the fastening hole 260. The horizontal frame 250 is installed in two members horizontally. When the two members are installed in this way, even if a load is added to the apparatus 10, the resistance to torsion is large and the apparatus is prevented from twisting.

An incision 262 is formed in the vertical block 230 for fixing the vertical block 230 by fastening the bolt with the fastening hole 260 and for smooth up and down of the vertical block 230 on the vertical frame 110. Is formed.

In addition, the restraint piece 200 has a plurality of fastening holes 280 for fastening the restraint device 220 and the rigid fixing, and tightening the bolt to the fastening hole 280, the restraint piece 200 is tightened, thereby The clamping device 220 is more strongly constrained by the repulsive force generated between the tightened bolt and the rectangular block 210, so that the problem of unwinding during the test does not occur.

Fig. 5 is a diagram showing various installation displacements of the frame rotation and the load adding device in the device according to the embodiment of the present invention.

As shown, the device according to an embodiment of the present invention is the rotation of the lower frame 120, the load is added to the left and right movement on the horizontal frame 250 of the device 10, the shankdong on the vertical frame 110 Rotational movement around the axis of the restraint device 140 is possible, such as the Shanghai-dong of the round bar.

6 is an exemplary view for explaining an example using a test apparatus according to an embodiment of the present invention.

As shown, the cabinet 36 is installed on the bottom plate 130. The cabinet 36 may be in a position other than the bottom plate 130.

After the load adding device 10 is positioned and fixed to the cabinet 36 in a position or direction to be pressurized, the pressure test on the cabinet 36 is performed. The load adding device 10 is provided with predetermined pressing means and can pressurize the cabinet 36. Since the load-adding means such as pressurization by the apparatus 10 may use various types, the detailed structure and operation thereof will not be described.

10 Load attachment device 100: Upper frame
110: vertical frame 120: lower frame
130: bottom plate 140: restraining device
150: bolt 160: fixture
200: restraint 210: moving block
220: restraining device 230: vertical block
240: round bar 250: horizontal frame
260: fastening hole 270: bolting hole
280: fastening hole

Claims (8)

In a test apparatus for measuring the rigidity of a mechanical structure, among the test apparatus for measuring the cabinet rigidity that can measure the rigidity of the cabinet structure,
Bottom plate 130,
A lower frame 120 installed on the bottom plate 130,
At least one pair of vertical frames 110 installed in parallel on the lower frame 120, and
A load adding device 10 installed on the vertical frame 110 so as to be installed to the left, right, up and down, and rotatably;
Cabinet stiffness test apparatus, characterized in that it comprises a top frame 100 for fixing the top to the vertical frame (110). The method of claim 1,
The lower frame 120 is provided with a restraining device 140, the lower frame 120 around the restraint device 140, the test for cabinet stiffness, characterized in that rotatably installed on the bottom plate 130 Device. The method of claim 1, wherein
Fixing device 160 is installed at both ends of the lower frame 120, the test apparatus for measuring the cabinet stiffness, characterized in that to install the vertical frame 110 perpendicular to the fixture 160 The method of claim 1,
The load adding device 10, the vertical block 230 is installed on each of the pair of vertical frame 110, and
Horizontal frame 250 for horizontally connecting between the vertical block 230 installed in each vertical frame 110,
A moving block 210 installed to be fixed to the horizontal frame 250, and
A restraining device 220 installed to be fixed to the movable block 210;
Cabinet stiffness test device, characterized in that it comprises a round bar 240 is fixed to the restraining device (220). The method of claim 4, wherein
The vertical block 230 is formed with a cutout 262 and a fastening hole 260 capable of fastening bolts, so that the vertical block 230 is fixed to the vertical frame 110 after the positional movement. Cabinet stiffness tester. The method of claim 4, wherein
An incision 228 is formed in the restraint device 220 to configure the round bar 240 to be fitted, and a bolt fastening hole 270 is formed in the restraint device 220 to form the round bar 240. Cabinet stiffness measurement test device, characterized in that configured to be fixed by bolt fastening after moving up and down position. The method of claim 4, wherein
The outer surface of the movable block 210 opposite to the restraining device 220 among the outer surfaces of the movable block 210 to be fixed on the horizontal frame 250 after the position movement in the horizontal direction 250 of the horizontal frame 250. The test piece for cabinet rigidity measurement, characterized in that the fixing piece 200 is coupled to the top. The method of claim 4, wherein
An end of the restraint device 220 is threaded to penetrate the moving block 210, and an end of the restraint device 220 passes through the restraint device 220 of the outer surface of the movable block 210. Cabinet stiffness measurement test device, characterized in that coupled with the fixing piece (200) disposed on the outer surface of the opposite side.

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