CN219871417U - Electrolytic capacitor test is with test equipment who has auxiliary positioning mechanism - Google Patents

Abstract

The utility model belongs to the technical field of test equipment, in particular to test equipment with an auxiliary positioning mechanism for an electrolytic capacitor test, which aims at the problems that the existing fixed electrolytic capacitor and the existing unfixed electrolytic capacitor are inconvenient to place and low in clamping efficiency and are unfavorable for improving the production efficiency because a pressing handle is required to be pressed, and the utility model provides a scheme that the test equipment comprises an aging machine box body, a box door and a box door, wherein the box door is movably hinged to the side end of the aging machine box body through a hinge shaft; the placing plate is fixedly connected to the bottom end of the sliding block; the mounting blocks are arranged at the top ends of the placing plates and used for placing the electrolytic capacitors; the plurality of groups of clamping and positioning mechanisms are respectively arranged in the plurality of mounting blocks and used for rapidly clamping and positioning the electrolytic capacitor; the clamping efficiency of multiunit extrusion mechanism is higher, is favorable to promoting production efficiency.

Description

Electrolytic capacitor test is with test equipment who has auxiliary positioning mechanism

Technical Field

The utility model relates to the technical field of test equipment, in particular to test equipment with an auxiliary positioning mechanism for an electrolytic capacitor test.

Background

The electrolytic capacitor has electrolyte material for storing charge inside, and has positive and negative polarity similar to that of cell, non-connectable negative polarity, positive electrode with metal substrate adhered oxide film and negative electrode connected via metal plate to electrolyte.

Through searching, chinese patent with patent publication number of CN213750134U discloses a fixture for aging test of aluminum electrolytic capacitors, comprising: the fixture body, the top of fixture body is equipped with the first clamping component that is used for the positive pole of centre gripping aluminium electrolytic capacitor and is used for the second clamping component of centre gripping aluminium electrolytic capacitor's negative pole. The first clamping assembly and the second clamping assembly each comprise: the clamping device comprises a fixed clamping piece, a movable clamping block and a clamping spring, wherein the fixed clamping piece is embedded in a clamp body, the movable clamping block is arranged in the clamp body in a sliding manner, and the clamping spring is arranged in the clamp body along the sliding direction of the movable clamping block and abuts against the movable clamping block and the fixed clamping piece. The fixed clamping piece is connected with an external power supply device through a wire, and a driving rod for driving the movable clamping block to slide is arranged in the clamp body in a sliding manner; in this patent, the fixed electrolytic capacitor and the fixed electrolytic capacitor are both required to be pressed to press the handle, and the clamping is efficient and unfavorable for improving production efficiency.

In view of the above problems, the present disclosure provides a test apparatus with an auxiliary positioning mechanism for an electrolytic capacitor test.

Disclosure of Invention

The utility model provides test equipment with an auxiliary positioning mechanism for an electrolytic capacitor test, which solves the defects that in the prior art, a pressing handle is required to be pressed for fixing and releasing the electrolytic capacitor, the placement is inconvenient, the clamping efficiency is low, and the production efficiency is not improved.

The utility model provides the following technical scheme:

the test equipment with the auxiliary positioning mechanism for the electrolytic capacitor test comprises an aging machine box body, wherein the aging machine box body comprises a box door, and the box door is movably hinged to the side end of the aging machine box body through a hinge shaft; the aging machine comprises a placing plate, wherein two sliding rails are arranged in the aging machine box, the surfaces of the two sliding rails are both connected with sliding blocks in a sliding manner, and the placing plate is fixedly connected to the bottom ends of the sliding blocks; the mounting blocks are arranged at the top ends of the placing plates and used for placing the electrolytic capacitors; the plurality of groups of clamping and positioning mechanisms are respectively arranged in the plurality of mounting blocks and used for rapidly clamping and positioning the electrolytic capacitor; the plurality of groups of extrusion mechanisms are respectively arranged in the mounting blocks and used for sending out the clamped and positioned electrolytic capacitors.

In one possible design, each group of clamping and positioning mechanisms comprises a containing groove which is arranged in the mounting block and used for containing an electrolytic capacitor, a first groove which is communicated with the containing groove is arranged in the mounting block, a positioning spring is fixedly connected in the first groove, a positioning plate is fixedly connected with the side end of the positioning spring, and the positioning plate is slidably connected in the containing groove.

In a possible design, every group extrusion mechanism all is including seting up in the installation piece with the second recess that the storage tank is linked together, two fixedly connected with gag lever posts in the second recess, two the circumference surface sliding connection of gag lever post has the lifter plate, the top fixedly connected with two extrusion springs of lifter plate, two the side of extrusion spring is all fixedly connected with in the second recess, two extrusion spring overlaps respectively locates the circumference surface of two gag lever posts, the top fixedly connected with spliced pole of lifter plate, the spliced pole upwards activity runs through to the storage tank in, the top fixedly connected with push pedal of spliced pole, the push pedal is located the electrolytic capacitor downside, sliding connection has the second extrusion plate in the second recess, the side fixedly connected with second trapezoidal extrusion piece of lifter plate, the inclined plane of second extrusion plate and second trapezoidal extrusion piece contacts, the side fixedly connected with connecting rod of second extrusion plate, the side end of connecting rod outwards runs through the side end of installation piece and outwards extends to have the connecting rod according to the fixedly connected with briquetting.

In one possible design, the top end of the second trapezoidal extrusion block is fixedly connected with a first trapezoidal extrusion block, the bottom end of the positioning plate is fixedly connected with a first extrusion plate, and the inclined surfaces of the first extrusion plate and the first trapezoidal extrusion block are in contact.

In one possible design, the side ends of the positioning plate and the inner wall of the accommodating groove are provided with anti-slip pads.

In one possible design, the mounting block is provided with a containing gap which is connected with the containing groove and is used for containing the anode pin and the cathode pin of the electrolytic capacitor.

In one possible design, the mounting block is provided with a hand-pinching gap at both ends.

In one possible design, the four corners of the bottom end of the aging box are fixedly connected with supporting legs, the side ends of the box door are fixedly connected with handles, and the handles and the supporting legs are kept horizontal after the box door is opened.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the utility model as claimed.

According to the utility model, the electrolytic capacitor is directly pressed into the mounting block by the positioning mechanism arranged in the mounting block, so that the electrolytic capacitor can be positioned and fixed by the positioning mechanism without additional pressing steps, the operation time is saved, meanwhile, the electrolytic capacitor can be rapidly sent out by the pressing mechanism, and the clamping efficiency is higher compared with the operation steps that the electrolytic capacitor is required to be pressed in the process of being released, and the production efficiency is improved.

Drawings

FIG. 1 is a first front perspective view of a test apparatus with an auxiliary positioning mechanism for testing an electrolytic capacitor according to an embodiment of the present utility model;

FIG. 2 is a second perspective view of a testing device with an auxiliary positioning mechanism for testing an electrolytic capacitor according to an embodiment of the present utility model;

FIG. 3 is a partial cross-sectional view of a test apparatus with an auxiliary positioning mechanism for testing electrolytic capacitors according to an embodiment of the present utility model;

fig. 4 is a partial perspective view of a test apparatus with an auxiliary positioning mechanism for testing an electrolytic capacitor according to an embodiment of the present utility model.

Reference numerals:

1. an aging machine box body; 2. support legs; 3. a door; 4. a handle; 5. placing a plate; 6. a slide rail; 7. a slide block; 8. a mounting block; 9. a receiving groove; 10. a first groove; 11. a positioning spring; 12. a positioning plate; 13. the accommodating gap; 14. a first pressing plate; 15. a first trapezoidal extrusion block; 16. a second pressing plate; 17. a second trapezoidal extrusion block; 18. a lifting plate; 19. a connecting column; 20. a second groove; 21. a limit rod; 22. extruding a spring; 23. a connecting rod; 24. pressing the blocks; 25. a hand pinching gap; 26. a push plate.

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the particular embodiments described herein are illustrative only and are not intended to limit the utility model, i.e., the embodiments described are merely some, but not all, of the embodiments of the utility model. The components of the embodiments of the present utility model generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations.

Example 1

Referring to fig. 1 to 4, a test apparatus with an auxiliary positioning mechanism includes an aging machine case 1, including a door 3, the door 3 being movably hinged to a side end of the aging machine case 1 by a hinge; the placing plate 5 is arranged in the aging machine box 1, two sliding rails 6 are arranged in the aging machine box 1, the surfaces of the two sliding rails 6 are both connected with sliding blocks 7 in a sliding manner, and the placing plate 5 is fixedly connected to the bottom ends of the sliding blocks 7; a plurality of mounting blocks 8, wherein the plurality of mounting blocks 8 are arranged at the top end of the placing plate 5 for placing the electrolytic capacitor; the plurality of groups of clamping and positioning mechanisms are respectively arranged in the plurality of mounting blocks 8 and used for rapidly clamping and positioning the electrolytic capacitor; the plurality of groups of extrusion mechanisms are respectively arranged in the mounting blocks 8 and used for sending out the electrolytic capacitors which are clamped and positioned.

Above-mentioned technical scheme can reach the positioning mechanism who locates in the installation piece 8, directly press the electrolytic capacitor and get into in the installation piece 8, can fix a position fixed electrolytic capacitor through positioning mechanism, need not additionally to press the step and fix electrolytic capacitor, saved operating time, simultaneously utilize extrusion mechanism can be quick with electrolytic capacitor upwards send out, only need press down the in-process that needs to be relieved electrolytic capacitor, compare in the operation step that the installation is fixed all needs to press down, clamping efficiency is higher, be favorable to promoting production efficiency's technical effect.

Referring to fig. 3, each group of clamping and positioning mechanisms comprises a containing groove 9 which is arranged in a mounting block 8 and used for containing an electrolytic capacitor, a first groove 10 which is communicated with the containing groove 9 is arranged in the mounting block 8, a positioning spring 11 is fixedly connected in the first groove 10, a positioning plate 12 is fixedly connected at the side end of the positioning spring 11, and the positioning plate 12 is slidably connected in the containing groove 9;

the side ends of the positioning plate 12 and the inner wall of the accommodating groove 9 are provided with anti-slip pads;

an accommodating gap 13 which is connected with the accommodating groove 9 and is used for accommodating the anode pin and the cathode pin of the electrolytic capacitor is arranged in the mounting block 8.

The technical scheme can achieve the technical effects that after the end part of the electrolytic capacitor is propped against the side end of the positioning plate 12, the accommodating gap 13 is plugged into the accommodating groove 9 downwards, the positioning plate 12 is pushed by the elasticity of the positioning spring 11, and the positioning plate 12 is matched with the side wall of the accommodating groove 9 to fix the position of the electrolytic capacitor;

the accommodating gap 13 is used for conveniently leaking the anode pin and the cathode pin of the electrolytic capacitor.

Referring to fig. 3 and 4, each group of extrusion mechanisms includes a second groove 20 which is formed in the mounting block 8 and is communicated with the accommodating groove 9, two limiting rods 21 are fixedly connected in the second groove 20, the circumferential surfaces of the two limiting rods 21 are slidably connected with a lifting plate 18, the top ends of the lifting plate 18 are fixedly connected with two extrusion springs 22, the side ends of the two extrusion springs 22 are fixedly connected in the second groove 20, the two extrusion springs 22 are respectively sleeved on the circumferential surfaces of the two limiting rods 21, the top ends of the lifting plate 18 are fixedly connected with connecting columns 19, the connecting columns 19 penetrate upwards and movably into the accommodating groove 9, the top ends of the connecting columns 19 are fixedly connected with pushing plates 26, the pushing plates 26 are located on the lower side of the electrolytic capacitor, the second groove 20 is slidably connected with a second extrusion plate 16, the side ends of the lifting plate 18 are fixedly connected with a second trapezoid extrusion block 17, the second extrusion plate 16 is contacted with the inclined surfaces of the second trapezoid extrusion block 17, the side ends of the second extrusion plate 16 are fixedly connected with connecting rods 23, the connecting rods 23 penetrate outwards and extend outwards through the side ends of the mounting block 8, and the connecting rods 24 are fixedly connected with the outer ends of the connecting rods 23.

According to the technical scheme, when the electrolytic capacitor needs to be taken out, the pressing block 24 is pressed, the pressing block 24 pushes the second extrusion plate 16 through the connecting rod 23, the second extrusion plate 16 extrudes the inclined plane of the second trapezoid extrusion block 17, the second trapezoid extrusion block 17 is subjected to upward movement of oiling, the second trapezoid extrusion block 17 drives the lifting plate 18 to move upward, the lifting plate 18 moves upward and drives the push plate 26 to move upward through the connecting column 19, and the electrolytic capacitor located in the accommodating groove 9 is pushed out upward.

The utility model can be used for electrolytic capacitor test and other fields suitable for the utility model.

Example 2

Referring to fig. 1 to 4, a test device with an auxiliary positioning mechanism for an electrolytic capacitor test comprises an aging machine box 1, a box door 3, a hinge shaft and a hinge shaft, wherein the box door 3 is movably hinged to the side end of the aging machine box 1; the placing plate 5 is arranged in the aging machine box 1, two sliding rails 6 are arranged in the aging machine box 1, the surfaces of the two sliding rails 6 are both connected with sliding blocks 7 in a sliding manner, and the placing plate 5 is fixedly connected to the bottom ends of the sliding blocks 7; a plurality of mounting blocks 8, wherein the plurality of mounting blocks 8 are arranged at the top end of the placing plate 5 for placing the electrolytic capacitor; the plurality of groups of clamping and positioning mechanisms are respectively arranged in the plurality of mounting blocks 8 and used for rapidly clamping and positioning the electrolytic capacitor; the plurality of groups of extrusion mechanisms are respectively arranged in the mounting blocks 8 and used for sending out the electrolytic capacitors which are clamped and positioned.

Above-mentioned technical scheme can reach the positioning mechanism who locates in the installation piece 8, directly press the electrolytic capacitor and get into in the installation piece 8, can fix a position fixed electrolytic capacitor through positioning mechanism, need not additionally to press the step and fix electrolytic capacitor, saved operating time, simultaneously utilize extrusion mechanism can be quick with electrolytic capacitor upwards send out, only need press down the in-process that needs to be relieved electrolytic capacitor, compare in the operation step that the installation is fixed all needs to press down, clamping efficiency is higher, be favorable to promoting production efficiency's technical effect.

Referring to fig. 3, each group of clamping and positioning mechanisms comprises a containing groove 9 which is arranged in a mounting block 8 and used for containing an electrolytic capacitor, a first groove 10 which is communicated with the containing groove 9 is arranged in the mounting block 8, a positioning spring 11 is fixedly connected in the first groove 10, a positioning plate 12 is fixedly connected at the side end of the positioning spring 11, and the positioning plate 12 is slidably connected in the containing groove 9;

the side ends of the positioning plate 12 and the inner wall of the accommodating groove 9 are provided with anti-slip pads;

an accommodating gap 13 which is connected with the accommodating groove 9 and is used for accommodating the anode pin and the cathode pin of the electrolytic capacitor is arranged in the mounting block 8.

The technical scheme can achieve the technical effects that after the end part of the electrolytic capacitor is propped against the side end of the positioning plate 12, the accommodating gap 13 is plugged into the accommodating groove 9 downwards, the positioning plate 12 is pushed by the elasticity of the positioning spring 11, and the positioning plate 12 is matched with the side wall of the accommodating groove 9 to fix the position of the electrolytic capacitor;

the accommodating gap 13 is used for conveniently leaking the anode pin and the cathode pin of the electrolytic capacitor.

Referring to fig. 3 and 4, each group of extrusion mechanisms includes a second groove 20 which is formed in the mounting block 8 and is communicated with the accommodating groove 9, two limiting rods 21 are fixedly connected in the second groove 20, the circumferential surfaces of the two limiting rods 21 are slidably connected with a lifting plate 18, the top ends of the lifting plate 18 are fixedly connected with two extrusion springs 22, the side ends of the two extrusion springs 22 are fixedly connected in the second groove 20, the two extrusion springs 22 are respectively sleeved on the circumferential surfaces of the two limiting rods 21, the top ends of the lifting plate 18 are fixedly connected with connecting columns 19, the connecting columns 19 penetrate upwards and movably into the accommodating groove 9, the top ends of the connecting columns 19 are fixedly connected with pushing plates 26, the pushing plates 26 are located on the lower side of the electrolytic capacitor, the second groove 20 is slidably connected with a second extrusion plate 16, the side ends of the lifting plate 18 are fixedly connected with a second trapezoid extrusion block 17, the second extrusion plate 16 is contacted with the inclined surfaces of the second trapezoid extrusion block 17, the side ends of the second extrusion plate 16 are fixedly connected with connecting rods 23, the connecting rods 23 penetrate outwards and extend outwards through the side ends of the mounting block 8, and the connecting rods 24 are fixedly connected with the outer ends of the connecting rods 23.

According to the technical scheme, when the electrolytic capacitor needs to be taken out, the pressing block 24 is pressed, the pressing block 24 pushes the second extrusion plate 16 through the connecting rod 23, the second extrusion plate 16 extrudes the inclined plane of the second trapezoid extrusion block 17, the second trapezoid extrusion block 17 is subjected to upward movement of oiling, the second trapezoid extrusion block 17 drives the lifting plate 18 to move upward, the lifting plate 18 moves upward and drives the push plate 26 to move upward through the connecting column 19, and the electrolytic capacitor located in the accommodating groove 9 is pushed out upward.

Referring to fig. 3, a first trapezoidal extrusion block 15 is fixedly connected to the top end of the second trapezoidal extrusion block 17, a first extrusion plate 14 is fixedly connected to the bottom end of the positioning plate 12, and the first extrusion plate 14 is in contact with the inclined surface of the first trapezoidal extrusion block 15; both ends of the mounting block 8 are provided with hand pinching gaps 25.

According to the technical scheme, the second trapezoid extrusion block 17 can ascend to drive the first trapezoid extrusion block 15 to ascend synchronously, the first trapezoid extrusion block 15 ascends to extrude the first extrusion plate 14 to move leftwards by using the inclined plane, the first extrusion plate 14 moves leftwards, the first extrusion plate 14 drives the positioning plate 12 to move leftwards to extrude the positioning spring 11, and meanwhile, the positioning of the electrolytic capacitor is relieved, so that the electrolytic capacitor is more convenient to take out;

the two hand pinching gaps 25 facilitate the pinching of the electrolytic capacitor carried by the pusher plate 26 by two fingers.

Referring to fig. 1 and 2, support legs 2 are fixedly connected to four corners of the bottom end of the aging box body 1, a handle 4 is fixedly connected to the side end of the box door 3, and the handle 4 and the support legs 2 are kept horizontal after the box door 3 is opened.

The technical scheme can achieve the technical effect that after the box door 3 is opened, the box door 3 and the ageing box body 1 are supported by the handle 4 to keep horizontal.

The working principle and the using flow of the technical scheme are as follows: after the end part of the electrolytic capacitor is propped against the side end of the positioning plate 12, the accommodating gap 13 is plugged downwards into the accommodating groove 9, the positioning plate 12 is pushed by the elasticity of the positioning spring 11, and the positioning plate 12 is matched with the side wall of the accommodating groove 9 to fix the position of the electrolytic capacitor;

when the electrolytic capacitor needs to be taken out, the pressing block 24 is pressed, the second pressing plate 16 is pushed by the pressing block 24 through the connecting rod 23, the second pressing plate 16 presses the inclined surface of the second trapezoid pressing block 17, the second trapezoid pressing block 17 is upwards moved by oiling, the second trapezoid pressing block 17 drives the lifting plate 18 to upwards move, the lifting plate 18 upwards moves and drives the push plate 26 to upwards move through the connecting column 19, the electrolytic capacitor located in the accommodating groove 9 is upwards pushed out, meanwhile, the second trapezoid pressing block 17 is lifted to drive the first trapezoid pressing block 15 to synchronously lift, the first trapezoid pressing block 15 is lifted to leftwards by the inclined surface to press the first pressing plate 14, the first pressing plate 14 is leftwards moved, the first pressing plate 14 leftwards drives the positioning plate 12 to leftwards move to press the positioning spring 11, and the positioning of the electrolytic capacitor is relieved, so that the electrolytic capacitor is more conveniently taken out.

The present utility model is not limited to the above embodiments, and any person skilled in the art can easily think about the changes or substitutions within the technical scope of the present utility model, and the changes or substitutions are intended to be covered by the scope of the present utility model; embodiments of the utility model and features of the embodiments may be combined with each other without conflict. Therefore, the protection scope of the utility model is subject to the protection scope of the claims.

Claims (8)

1. Test equipment with auxiliary positioning mechanism for electrolytic capacitor test, including ageing machine box (1), its characterized in that includes:

the box door (3), the box door (3) is articulated with the side end of the aging box body (1) through a hinge shaft;

the aging machine comprises a placement plate (5), wherein two sliding rails (6) are arranged in a box body (1) of the aging machine, sliding blocks (7) are slidably connected to the surfaces of the two sliding rails (6), and the placement plate (5) is fixedly connected to the bottom ends of the sliding blocks (7);

a plurality of mounting blocks (8), wherein the mounting blocks (8) are arranged at the top end of the placing plate (5) for placing the electrolytic capacitor;

the plurality of groups of clamping and positioning mechanisms are respectively arranged in the plurality of mounting blocks (8) and used for rapidly clamping and positioning the electrolytic capacitor;

the plurality of groups of extrusion mechanisms are respectively arranged in the mounting blocks (8) and used for sending out the electrolytic capacitors which are clamped and positioned.

2. The test device with the auxiliary positioning mechanism for the electrolytic capacitor test according to claim 1, wherein each group of the clamping positioning mechanisms comprises a containing groove (9) which is arranged in the mounting block (8) and used for containing the electrolytic capacitor, a first groove (10) which is communicated with the containing groove (9) is formed in the mounting block (8), a positioning spring (11) is fixedly connected in the first groove (10), a positioning plate (12) is fixedly connected to the side end of the positioning spring (11), and the positioning plate (12) is slidably connected in the containing groove (9).

3. The test device with an auxiliary positioning mechanism for an electrolytic capacitor according to claim 2, wherein each group of the extrusion mechanisms comprises a second groove (20) which is arranged in the mounting block (8) and communicated with the accommodating groove (9), two limiting rods (21) are fixedly connected in the second groove (20), lifting plates (18) are slidably connected to the circumferential surfaces of the two limiting rods (21), two extrusion springs (22) are fixedly connected to the top ends of the lifting plates (18), the side ends of the two extrusion springs (22) are fixedly connected to the circumferential surfaces of the second groove (20), the two extrusion springs (22) are respectively sleeved on the circumferential surfaces of the two limiting rods (21), the top ends of the lifting plates (18) are fixedly connected with connecting columns (19), the connecting columns (19) are upwards and movably penetrated into the accommodating groove (9), the top ends of the connecting columns (19) are fixedly connected with pushing plates (26), the pushing plates (26) are positioned on the lower sides of the electrolytic capacitor, the side of the second groove (20) are fixedly connected with the second pressing blocks (16), the second pressing plates (16) are fixedly connected with the inner sliding blocks (16), the second pressing plates (16) are fixedly connected with the second pressing blocks (17), the connecting rod (23) outwards penetrates through the side end of the mounting block (8) in a movable mode and outwards extends, and the side end of the connecting rod (23) is fixedly connected with the pressing block (24).

4. A test device with an auxiliary positioning mechanism for an electrolytic capacitor test according to claim 3, wherein the top end of the second trapezoidal extrusion block (17) is fixedly connected with a first trapezoidal extrusion block (15), the bottom end of the positioning plate (12) is fixedly connected with a first extrusion plate (14), and the first extrusion plate (14) is contacted with the inclined surface of the first trapezoidal extrusion block (15).

5. The test equipment with the auxiliary positioning mechanism for the electrolytic capacitor test according to claim 4, wherein the side end of the positioning plate (12) and the inner wall of the accommodating groove (9) are both provided with anti-slip pads.

6. The test equipment with the auxiliary positioning mechanism for the electrolytic capacitor test according to claim 5, wherein the installation block (8) is internally provided with a containing gap (13) which is connected with the containing groove (9) and is universal for containing the anode pin and the cathode pin of the electrolytic capacitor.

7. The test equipment with the auxiliary positioning mechanism for the electrolytic capacitor test according to claim 6, wherein the two ends of the mounting block (8) are provided with hand pinching gaps (25).

8. The test device with an auxiliary positioning mechanism for an electrolytic capacitor test according to any one of claims 1 to 7, wherein supporting legs (2) are fixedly connected to four corners of the bottom end of the case body (1), a handle (4) is fixedly connected to the side end of the case door (3), and the handle (4) and the supporting legs (2) are kept horizontal after the case door (3) is opened.