CN114563139A - Stainless steel heat preservation container detection device - Google Patents

Abstract

The invention relates to the technical field of container detection, and discloses a stainless steel heat-insulating container detection device which comprises two side plates which are oppositely arranged, wherein a shaking shaft is movably arranged on one opposite side of each of the two side plates, a bearing sleeve is fixedly arranged between the two shaking shafts, a heat-insulating container is arranged in the bearing sleeve, and a shaking mechanism arranged in the side plates drives the bearing sleeve and the heat-insulating container to move up and down through the shaking shafts so as to detect whether the heat-insulating container leaks or not; the heat preservation container is placed on the anti-drop ring of the bearing sleeve, the bearing sleeve can be moved up and down by controlling the operation of the driving motor, and the bearing sleeve is moved up and down to drive the heat preservation container to move up and down, so that the heat preservation container can be subjected to leakage detection, and whether the heat preservation container leaks water or not can be detected. The invention has the advantages of novel design and simple structure, and can accurately detect whether the heat-insulating container leaks water.

Description

Stainless steel heat preservation container detection device

Technical Field

The invention relates to the technical field of container detection, in particular to a stainless steel heat-preservation container detection device.

Background

Heat preservation containers such as heat preservation cups and the like not only have higher requirements on heat preservation performance, but also have the characteristic of good sealing property, so that the daily use requirements can be met; therefore, in quality inspection of the heat-insulating container, the inspection of the sealing property is an essential step.

In the prior art, the detection of the sealing performance of the heat preservation container is mainly performed by manual detection, and has the defects of poor detection precision, high labor intensity, low detection efficiency and the like, so how to realize industrial automatic detection is urgently needed to be completed.

Disclosure of Invention

Technical problem to be solved

Aiming at the defects of the prior art, the invention provides a stainless steel heat-insulating container detection device which has the advantage of being capable of accurately detecting whether the heat-insulating container leaks water or not.

(II) technical scheme

In order to achieve the purpose of accurately detecting whether the heat-insulating container leaks water, the invention provides the following technical scheme: the utility model provides a stainless steel heat preservation container detection device, includes two curb plates that set up relatively, two one side that the curb plate is relative all moves about and is provided with the axle of shaking, two shake fixed mounting between the axle of shaking and have a bearing cover, be provided with the heat preservation container in the bearing cover, set up the mechanism of shaking in the curb plate, drive bearing cover and heat preservation container through shaking the axle of shaking and reciprocate in order to detect whether the seepage of heat preservation container.

As a preferred technical scheme of the invention, the shaking mechanism comprises a driving motor, eccentric wheels, a top plate, vertical shafts, a first spring and a positioning plate, wherein the driving motor is fixedly installed on the outer wall of the side plate, the eccentric wheels are fixedly installed at the tops of output shafts of the driving motor, the eccentric wheels are movably arranged in the side plate, the top plate is movably arranged at the tops of the eccentric wheels, the vertical shafts are fixedly installed on the left side and the right side of the top plate, and the top ends of the two vertical shafts extend to the outside of the side plate;

the outer walls of the two vertical shafts are also sleeved with first springs, the first springs are fixedly connected between the top of the top plate and the bottom of the positioning plate, and the positioning plate is fixedly installed on the inner top wall of the side plate;

the shaking shaft is fixedly installed on the outer wall of the top plate, and the outer wall of the side plate is further provided with a movable groove corresponding to the shaking shaft.

As a preferred technical scheme of the invention, the bottom of the inner wall of the bearing sleeve is fixedly provided with an anti-falling ring, and the heat-insulating container is placed on the anti-falling ring.

As a preferred technical scheme of the invention, a drainage slope surface is formed at the top of the inner wall of the bearing sleeve, and drainage holes are uniformly formed in the inner side wall of the bearing sleeve.

As a preferred technical scheme of the invention, a first side cabinet and a second side cabinet are respectively arranged at the front side and the rear side of the two side plates, a driving roller and a driven roller are respectively and movably arranged in the first side cabinet and the second side cabinet, test paper is wound on the driving roller, and the tail end of the test paper is connected with the driven roller.

As a preferred technical scheme of the present invention, a fixing plate is fixedly installed between the two vertical shafts, an adjusting motor is fixedly installed at the bottom of the fixing plate, a lead screw is fixedly installed at the top of an output shaft of the adjusting motor, a screw nut is connected to the outer wall of the lead screw in a threaded manner, a connecting rod is fixedly installed on the outer wall of the screw nut, and a pressing cylinder is fixedly installed at the tail end of the connecting rod.

As a preferred technical scheme of the invention, the heat-insulating container consists of a cup body and a cup cover, wherein the cup cover is in threaded connection with the outer wall of the top of the cup body.

As a preferred technical scheme of the invention, the inner wall of the pressing cylinder is connected with a rotating cylinder through a positioning bearing, the outer wall of the rotating cylinder is uniformly provided with external teeth, the outer wall of the external teeth is meshed with a driving wheel, the driving wheel is fixedly installed at the bottom of an output shaft of a tightening motor, and the tightening motor is fixedly installed on the outer wall of the pressing cylinder;

a gland plate is arranged in the rotating cylinder, a vertical rod is fixedly mounted at the top of the gland plate, and the top end of the vertical rod extends to the outside of the pressing cylinder;

the outer wall of the vertical rod is further sleeved with a second spring, and the second spring is fixedly connected between the top of the pressing cover plate and the inner top wall of the pressing barrel.

As a preferred technical scheme of the invention, a plurality of rotating sleeves are uniformly arranged around the gland plate, the rotating sleeves are rotatably arranged on a fixed rod through torsional springs, and two ends of the fixed rod are fixedly arranged on the inner wall of the pressing cylinder;

a push plate is fixedly installed at the top of the rotating sleeve, and an arc-shaped surface is formed on one side of the push plate, which faces the gland plate;

and a clamping plate is fixedly arranged at the bottom of the rotating sleeve.

As a preferable technical solution of the present invention, a support bearing is disposed at the bottom of the gland plate, a vertical groove is formed at the center of the inside of the gland plate, an elastic hose is disposed at the top of the vertical groove, and the top end of the elastic hose extends to the outside of the pressure cylinder.

(III) advantageous effects

Compared with the prior art, the invention provides a stainless steel heat-insulating container detection device, which has the following beneficial effects:

1. this stainless steel insulated container detection device places insulated container on the anticreep ring of bearing the cover, and control driving motor operation can make and bear the cover and reciprocate, bears the cover and reciprocates and drive insulated container and reciprocate to can carry out the seepage detection to insulated container, detect insulated container whether leak.

2. This stainless steel heat preservation container detection device, driving motor operate and drive the eccentric wheel rotation at its output shaft top, and eccentric wheel rotation cycle promotes the roof and upwards removes, and roof circulation upwards removes can drive bearing cover and heat preservation container circulation upwards removal through shaking the moving axis, detects whether heat preservation container leaks.

3. According to the stainless steel heat-preservation container detection device, test paper is wound on the driving roller, the tail end of the test paper is connected with the driven roller, whether the heat-preservation container leaks water can be detected through the test paper, if the heat-preservation container leaks water, leaked water drops fall on the test paper, color development can be achieved, and therefore whether the heat-preservation container leaks water or not can be conveniently judged;

after the test paper is used, the test paper can be gradually wound on the driven roller from the driving roller by controlling the rotation of the driving roller and the driven roller, so that the test paper below the heat-insulating container is kept fresh, and the detection of water leakage is facilitated.

4. This stainless steel insulated container detection device, the top that bears the weight of the cover inner wall is formed with the drainage domaticly, and the drainage hole has evenly been seted up to the inside wall that bears the weight of the cover, and the water that insulated container seepage leaked can not blockked by the anticreep ring through the smooth and easy flow down in drainage domatic and drainage hole of drainage, and detection effect is better.

5. This stainless steel heat preservation container detection device, roof circulation rebound when driving bearing sleeve and heat preservation container circulation rebound through shaking the moving axis, still can drive two vertical axis circulation rebound simultaneously, be provided with the fixed plate between two vertical axes, the fixed plate bottom is provided with adjusting motor, the operation of control adjusting motor can make the lead screw at its output shaft top rotatory, the lead screw is rotatory to be driven the screw of its outer wall threaded connection and reciprocates, the screw reciprocates and can drive a pressure section of thick bamboo through the connecting rod and reciprocate, the position of a section of thick bamboo is pressed in the adjustment, thereby, after placing heat preservation container in bearing sleeve, can make a pressure section of thick bamboo descend through adjusting motor, press the top at heat preservation container, prevent that heat preservation container from dropping at the in-process of rocking from top to bottom.

6. This stainless steel heat preservation container detection device, when making a pressure section of thick bamboo decline pressure at the heat preservation container top, the pressure apron still can upwards be promoted by heat preservation container, it is rotatory that the pressure apron rebound promotes the push pedal, the push pedal is rotatory to drive splint rotation through rotating the cover, thereby make splint centre gripping at the top of heat preservation container, if heat preservation container comprises cup and bowl cover that the screw thread links to each other, splint just centre gripping is on the bowl cover this moment, the splint centre gripping is after on the bowl cover, the motor operation is screwed up in control can make the drive wheel rotatory, the drive wheel is rotatory to drive a rotation section of thick bamboo through the external tooth, it can drive the bowl cover rotation through splint to rotate a section of thick bamboo rotation, make tightly twisting of bowl cover on the cup, be convenient for carry out the seepage detection under the state of screwing up the bowl cover.

Drawings

FIG. 1 is a perspective view of the overall structure of the present invention;

FIG. 2 is a cross-sectional view of a side panel portion of the present invention;

FIG. 3 is an enlarged schematic view of the cup portion of the present invention;

FIG. 4 is a cross-sectional view of a portion of the load bearing sleeve of the present invention;

FIG. 5 is an enlarged schematic view of a lead screw portion of the present invention;

FIG. 6 is a cross-sectional view of a platen portion of the present invention;

FIG. 7 is a front sectional view of the barrel pressing portion of the present invention;

FIG. 8 is an enlarged view taken at A of FIG. 7 in accordance with the present invention;

FIG. 9 is an enlarged view of a portion of the test strip of the present invention.

In the figure: 1. a side plate; 2. shaking the moving shaft; 3. a bearing sleeve; 4. a cup body; 5. a cup cover; 6. a drive motor; 7. an eccentric wheel; 8. a top plate; 9. a vertical axis; 10. a first spring; 11. positioning a plate; 12. the anti-drop ring; 13. drainage slope; 14. a drainage hole; 15. a fixing plate; 16. adjusting the motor; 17. a screw rod; 18. a screw nut; 19. a slider; 20. a connecting rod; 21. pressing the cylinder; 22. positioning the bearing; 23. a rotating cylinder; 24. external teeth; 25. a drive wheel; 26. screwing down the motor; 27. pressing a cover plate; 28. a vertical rod; 29. a second spring; 30. fixing the rod; 31. rotating the sleeve; 32. pushing a plate; 33. an arc-shaped surface; 34. a splint; 35. a support bearing; 36. a vertical slot; 37. an elastic hose; 38. a first side cabinet; 39. a second side cabinet; 40. a drive roll; 41. a driven roller; 42. and (4) test paper.

Detailed Description

Example (b):

referring to fig. 1-9, a stainless steel thermal insulation container detection device includes two side plates 1 disposed oppositely, a shaking axis 2 is movably disposed on one side of each of the two side plates 1 opposite to each other, a bearing sleeve 3 is fixedly disposed between the two shaking axis 2, an anti-drop ring 12 is fixedly disposed on the bottom of the inner wall of the bearing sleeve 3, a thermal insulation container is disposed on the anti-drop ring 12, and a shaking mechanism disposed in the side plates 1 drives the bearing sleeve 3 and the thermal insulation container to move up and down through the shaking axis 2 to detect whether the thermal insulation container leaks;

in this embodiment, as shown in fig. 2, the rocking mechanism includes a driving motor 6, an eccentric wheel 7, a top plate 8, a vertical shaft 9, a first spring 10 and a positioning plate 11, the driving motor 6 is fixedly installed on the outer wall of the side plate 1, the eccentric wheel 7 is fixedly installed on the top of an output shaft of the driving motor 6, the eccentric wheel 7 is movably arranged in the side plate 1, the top plate 8 is movably arranged on the top of the eccentric wheel 7, the rocking shaft 2 is fixedly installed on the outer wall of the top plate 8, and the outer wall of the side plate 1 is further provided with a movable groove corresponding to the rocking shaft 2;

during the use, place insulating container on the anticreep ring 12 of bearing cover 3, control driving motor 6 operation can make bearing cover 3 reciprocate, and bearing cover 3 reciprocates and drives insulating container and reciprocates to can carry out the leakage detection to insulating container, detect whether insulating container leaks, it is specific:

the driving motor 6 operates to drive the eccentric wheel 7 at the top of the output shaft of the driving motor to rotate, the eccentric wheel 7 rotates to circularly push the top plate 8 to move upwards, the top plate 8 circularly moves upwards and can drive the bearing sleeve 3 and the heat-preservation container to circularly move upwards through the shaking shaft 2, and whether water leaks from the heat-preservation container is detected;

as shown in fig. 9, a first side cabinet 38 and a second side cabinet 39 are respectively arranged on the front side and the rear side of the two side plates 1, a driving roller 40 and a driven roller 41 are respectively movably arranged in the first side cabinet 38 and the second side cabinet 39, a test paper 42 is wound on the driving roller 40, and the tail end of the test paper 42 is connected with the driven roller 41;

whether the heat preservation container leaks water can be detected through the test paper 42, if the heat preservation container leaks water, the leaked water can be dripped on the test paper 42 to be colored, whether the heat preservation container leaks water or not is conveniently judged, after the test paper 42 is used, the drive roller 40 and the driven roller 41 are controlled to rotate, the test paper 42 can be gradually wound on the driven roller 41 from the drive roller 40, and therefore the test paper 42 below the heat preservation container is kept to be fresh, water leakage can be conveniently detected, in the embodiment, the test paper 42 is the cobalt chloride test paper 42, and other test paper 42 capable of coloring water can be selected and arranged according to actual needs;

in the embodiment, the driving roller 40 and the driven roller 41 are driven by the motor to rotate, so that the test paper 42 is convenient to move, and the test paper 42 below the heat-insulating container is kept fresh;

as shown in fig. 3 and 4, a drainage slope 13 is formed at the top of the inner wall of the bearing sleeve 3, drainage holes 14 are uniformly formed in the inner side wall of the bearing sleeve 3, water leaked from the heat preservation container can smoothly flow down through the drainage slope 13 and the drainage holes 14 and cannot be blocked by the anti-drop ring 12, the detection effect is better, and the leaked water is prevented from being blocked by the heat preservation container and cannot flow out;

as shown in fig. 2, vertical shafts 9 are fixedly mounted on the left side and the right side of the top plate 8, the top ends of the two vertical shafts 9 extend to the outside of the side plate 1, first springs 10 are further sleeved on the outer walls of the two vertical shafts 9, the first springs 10 are fixedly connected between the top of the top plate 8 and the bottom of a positioning plate 11, the positioning plate 11 is fixedly mounted on the inner top wall of the side plate 1, when the top plate 8 is pushed by the eccentric wheel 7 to move upwards, the two vertical shafts 9 are driven to move upwards, at the same time, the first springs 10 are compressed, and when the telecentric end of the eccentric wheel 7 rotates to the lower side, the top plate 8 can descend under the elastic force of the first springs 10;

as shown in fig. 5, a fixing plate 15 is fixedly installed between two vertical shafts 9, an adjusting motor 16 is fixedly installed at the bottom of the fixing plate 15, a lead screw 17 is fixedly installed at the top of an output shaft of the adjusting motor 16, a screw 18 is connected to the outer wall of the lead screw 17 through a thread, a connecting rod 20 is fixedly installed on the outer wall of the screw 18, and a pressing cylinder 21 is fixedly installed at the tail end of the connecting rod 20;

the top plate 8 circularly moves upwards, the bearing sleeve 3 and the heat preservation container are driven to circularly move upwards through the shaking shaft 2, meanwhile, the two vertical shafts 9 are driven to circularly move upwards, the fixing plate 15 is arranged between the two vertical shafts 9, the bottom of the fixing plate 15 is provided with the adjusting motor 16, the operation of the adjusting motor 16 is controlled to enable the screw rod 17 at the top of the output shaft to rotate, the screw rod 17 rotates to drive the screw nut 18 in threaded connection with the outer wall of the screw nut to move upwards and downwards, the screw nut 18 moves upwards and downwards to drive the pressing cylinder 21 to move upwards and downwards through the connecting rod 20, and the position of the pressing cylinder 21 is adjusted, so that after the heat preservation container is placed in the bearing sleeve 3, the pressing cylinder 21 can be lowered through the adjusting motor 16 and pressed on the top of the heat preservation container, and the heat preservation container is prevented from falling down and upwards in the shaking process;

in this embodiment, the outer wall of the screw 18 is provided with a sliding block 19, the sliding block 19 is slidably arranged on the outer wall of the vertical shaft 9, and the sliding arrangement of the sliding block 19 on the vertical shaft 9 limits the rotation of the screw 18, so that the screw 18 can only be driven by the screw rod 17 to perform up-and-down translational motion;

in an alternative embodiment, the heat preservation container is composed of a cup body 4 and a cup cover 5, wherein the cup cover 5 is in threaded connection with the outer wall of the top of the cup body 4, which is also the most common heat preservation container in daily life;

as shown in fig. 6, the inner wall of the pressing cylinder 21 is connected with a rotating cylinder 23 through a positioning bearing 22, the outer wall of the rotating cylinder 23 is uniformly provided with external teeth 24, the outer wall of the external teeth 24 is engaged with a driving wheel 25, the driving wheel 25 is fixedly installed at the bottom of the output shaft of the tightening motor 26, the tightening motor 26 is fixedly installed on the outer wall of the pressing cylinder 21, the tightening motor 26 operates to drive the driving wheel 25 at the top of the output shaft to rotate, and the driving wheel 25 rotates to drive the rotating cylinder 23 to rotate through the engaged external teeth 24;

a gland plate 27 is arranged in the rotating cylinder 23, a vertical rod 28 is fixedly installed at the top of the gland plate 27, the top end of the vertical rod 28 extends to the outside of the pressing cylinder 21, a second spring 29 is further sleeved on the outer wall of the vertical rod 28, and the second spring 29 is fixedly connected between the top of the gland plate 27 and the inner top wall of the pressing cylinder 21;

a plurality of rotating sleeves 31 are uniformly arranged around the pressure cover plate 27, the rotating sleeves 31 are rotatably arranged on the fixing rod 30 through torsion springs, two ends of the fixing rod 30 are fixedly arranged on the inner wall of the pressure cylinder 21, a push plate 32 is fixedly arranged at the top of the rotating sleeve 31, an arc surface 33 is formed on one side of the push plate 32 facing the pressure cover plate 27, and a clamping plate 34 is fixedly arranged at the bottom of the rotating sleeve 31;

when the pressing cylinder 21 is pressed down to the top of the heat-insulating container, the pressing cover plate 27 can be pushed upwards by the heat-insulating container, the pressing cover plate 27 moves upwards to push the push plate 32 to rotate, the push plate 32 rotates to drive the clamp plate 34 to rotate through the rotating sleeve 31, so that the clamp plate 34 is clamped at the top of the heat-insulating container, if the heat-insulating container consists of the cup body 4 and the cup cover 5 which are connected through threads, the clamp plate 34 is clamped on the cup cover 5 at the moment, after the clamp plate 34 is clamped on the cup cover 5, the driving wheel 25 can be rotated by controlling the operation of the screwing motor 26, the driving wheel 25 rotates to drive the rotating cylinder 23 to rotate through the external teeth 24, the rotating cylinder 23 rotates to drive the cup cover 5 to rotate through the clamp plate 34, so that the cup cover 5 is tightly screwed on the cup body 4, leakage detection is convenient to be carried out in a state of screwing the cup cover 5, and an automatic cover screwing effect is also achieved;

therefore, in the embodiment, the pressing cylinder 21 can not only shake along with the shaking shaft 2 to play a role in preventing the heat preservation container from falling off, but also automatically screw the cup cover 5 under the condition of 'leakage detection of the heat preservation cup', so that the functions are more diversified, and the detection effect is better;

as shown in fig. 7, a support bearing 35 is arranged at the bottom of the gland plate 27, a vertical groove 36 is formed at the center inside the gland plate 27, an elastic hose 37 is arranged at the top of the vertical groove 36, the top end of the elastic hose 37 extends to the outside of the pressure cylinder 21, hot water can be filled through the elastic hose 37, the filled hot water is discharged through the vertical groove 36, if only the cup body 4 is placed on the anti-drop ring 12 at the moment, and the cup cover 5 is not placed, the hot water can flow into the cup body 4, so that hot water for detection experiments can be added into the cup body 4;

through the arrangement of the supporting bearing 35, the cup cover 5 and the gland plate 27 can freely rotate, the situation that the cup cover 5 is tightly pressed and cannot rotate is avoided, and in order to prevent the cup body 4 and the cup cover 5 from rotating together, in the embodiment, the bearing sleeve 3 is provided with the anti-skid rubber ring at the position staggered with the drainage hole 14, so that the cup body 4 can be prevented from rotating in the bearing sleeve 3;

in the embodiment, during detection, the cup body 4 is placed on the anti-drop ring 12, then hot water with the volume of 50% above 90 ℃ is filled into the cup body 4 through the elastic hose 37, after the hot water is filled, the cup cover 5 is placed on the cup body 4, then the cup cover 5 is screwed through the clamping plate 34, and after the cup cover 5 is screwed, the heat-insulating container is shaken up and down for ten times at an amplitude of 500mm each time once a second through the driving motor 6 to detect whether water leaks.

The working principle and the using process of the invention are as follows:

during the use, place insulating container on the anticreep ring 12 of bearing cover 3, control driving motor 6 operation can make bearing cover 3 reciprocate, and bearing cover 3 reciprocates and drives insulating container and reciprocates to can carry out the leakage detection to insulating container, detect whether insulating container leaks, it is specific:

the driving motor 6 operates to drive the eccentric wheel 7 at the top of the output shaft of the driving motor to rotate, the eccentric wheel 7 rotates to circularly push the top plate 8 to move upwards, the top plate 8 circularly moves upwards and can drive the bearing sleeve 3 and the heat-preservation container to circularly move upwards through the shaking shaft 2, and whether water leaks from the heat-preservation container is detected;

the test paper 42 is wound on the driving roller 40, the tail end of the test paper 42 is connected with the driven roller 41, whether the heat preservation container leaks water or not can be detected through the test paper 42, if the heat preservation container leaks water, the leaked water drops on the test paper 42 to be capable of developing color, and therefore whether the heat preservation container leaks water or not can be conveniently judged;

after the test paper 42 is used, the test paper 42 can be gradually wound from the drive roller 40 to the driven roller 41 by controlling the drive roller 40 and the driven roller 41 to rotate, so that the test paper 42 below the heat-insulating container is kept fresh, and the detection of water leakage is facilitated;

a drainage slope surface 13 is formed at the top of the inner wall of the bearing sleeve 3, drainage holes 14 are uniformly formed in the inner side wall of the bearing sleeve 3, water leaked out of the heat preservation container can smoothly flow down through the drainage slope surface 13 and the drainage holes 14 and cannot be blocked by the anti-drop ring 12, and the detection effect is better;

the top plate 8 circularly moves upwards, the bearing sleeve 3 and the heat preservation container are driven to circularly move upwards through the shaking shaft 2, meanwhile, the two vertical shafts 9 are driven to circularly move upwards, the fixing plate 15 is arranged between the two vertical shafts 9, the bottom of the fixing plate 15 is provided with the adjusting motor 16, the operation of the adjusting motor 16 is controlled to enable the screw rod 17 at the top of the output shaft to rotate, the screw rod 17 rotates to drive the screw nut 18 in threaded connection with the outer wall of the screw nut to move upwards and downwards, the screw nut 18 moves upwards and downwards to drive the pressing cylinder 21 to move upwards and downwards through the connecting rod 20, and the position of the pressing cylinder 21 is adjusted, so that after the heat preservation container is placed in the bearing sleeve 3, the pressing cylinder 21 can be lowered through the adjusting motor 16 and pressed on the top of the heat preservation container, and the heat preservation container is prevented from falling down and upwards in the shaking process;

make pressing a section of thick bamboo 21 to descend and press at the heat preservation container top simultaneously, pressing apron 27 still can upwards be promoted by the heat preservation container, pressing apron 27 rebound promotes the push pedal 32 rotatory, push pedal 32 is rotatory to drive splint 34 rotatory through rotating cover 31, thereby make splint 34 centre gripping at the top of heat preservation container, if the heat preservation container comprises cup 4 and bowl cover 5 that the screw thread links to each other, then splint 34 just the centre gripping is on bowl cover 5 this moment, splint 34 centre gripping is after on bowl cover 5, control screwing up motor 26 operation and can make drive wheel 25 rotatory, drive wheel 25 is rotatory to drive a section of thick bamboo 23 through external tooth 24 and rotate, a section of thick bamboo 23 rotation can drive bowl cover 5 through splint 34 and rotate, make bowl cover 5 tightly screw on cup 4, thereby be convenient for carry out the bowl cover seepage detection under the state of screwing up 5, the effect of automatic screwing up lid has also been reached.

Claims (10)

1. The utility model provides a stainless steel heat preservation container detection device, includes two curb plates (1) of relative setting, its characterized in that: two one side that curb plate (1) is relative is all movable to be provided with shakes moving axis (2), two shake fixed mounting between moving axis (2) and bear cover (3), be provided with the insulated container in bearing cover (3), set up the mechanism that rocks in curb plate (1), drive through shaking moving axis (2) and bear cover (3) and insulated container and reciprocate in order to detect whether the insulated container leaks.

2. The stainless steel thermal insulation container detection device according to claim 1, characterized in that: the shaking mechanism comprises a driving motor (6), eccentric wheels (7), a top plate (8), vertical shafts (9), a first spring (10) and a positioning plate (11), the driving motor (6) is fixedly installed on the outer wall of the side plate (1), the eccentric wheels (7) are fixedly installed at the tops of output shafts of the driving motor (6), the eccentric wheels (7) are movably arranged in the side plate (1), the top plate (8) is movably arranged at the tops of the eccentric wheels (7), the vertical shafts (9) are fixedly installed on the left side and the right side of the top plate (8), and the top ends of the two vertical shafts (9) extend to the outside of the side plate (1);

the outer walls of the two vertical shafts (9) are further sleeved with first springs (10), the first springs (10) are fixedly connected between the top of the top plate (8) and the bottom of the positioning plate (11), and the positioning plate (11) is fixedly installed on the inner top wall of the side plate (1);

the shaking moving shaft (2) is fixedly arranged on the outer wall of the top plate (8), and the outer wall of the side plate (1) is further provided with a moving groove corresponding to the shaking moving shaft (2).

3. The stainless steel thermal insulation container detection device according to claim 1, characterized in that: the bottom of the inner wall of the bearing sleeve (3) is fixedly provided with an anti-falling ring (12), and the heat-insulating container is placed on the anti-falling ring (12).

4. The stainless steel thermal insulation container detection device according to claim 3, characterized in that: the top of bearing sleeve (3) inner wall is formed with drainage domatic (13), drainage hole (14) have evenly been seted up to the inside wall of bearing sleeve (3).

5. The stainless steel thermal insulation container detection device according to claim 1, characterized in that: the front side and the rear side of each of the two side plates (1) are respectively provided with a first side cabinet (38) and a second side cabinet (39), a driving roller (40) and a driven roller (41) are respectively and movably arranged in the first side cabinet (38) and the second side cabinet (39), test paper (42) is wound on the driving roller (40), and the tail end of the test paper (42) is connected with the driven roller (41).

6. The stainless steel thermal insulation container detection device according to claim 2, characterized in that: two fixed mounting has fixed plate (15) between vertical axis (9), the bottom fixed mounting of fixed plate (15) has adjusting motor (16), the output shaft top fixed mounting of adjusting motor (16) has lead screw (17), the outer wall threaded connection of lead screw (17) has screw (18), the outer wall fixed mounting of screw (18) has connecting rod (20), the terminal fixed mounting of connecting rod (20) has a pressure section of thick bamboo (21).

7. The stainless steel thermal insulation container detection device according to claim 6, characterized in that: the heat preservation container is composed of a cup body (4) and a cup cover (5), wherein the cup cover (5) is in threaded connection with the outer wall of the top of the cup body (1).

8. The stainless steel thermal insulation container detection device according to claim 7, characterized in that: the inner wall of the pressing cylinder (21) is connected with a rotating cylinder (23) through a positioning bearing (22), outer teeth (24) are uniformly arranged on the outer wall of the rotating cylinder (23), the outer wall of each outer tooth (24) is meshed with a driving wheel (25), the driving wheel (25) is fixedly installed at the bottom of an output shaft of a tightening motor (26), and the tightening motor (26) is fixedly installed on the outer wall of the pressing cylinder (21);

a gland plate (27) is arranged in the rotating cylinder (23), a vertical rod (28) is fixedly installed at the top of the gland plate (27), and the top end of the vertical rod (28) extends to the outside of the pressing cylinder (21);

the outer wall of the vertical rod (28) is further sleeved with a second spring (29), and the second spring (29) is fixedly connected between the top of the gland plate (27) and the inner top wall of the pressure cylinder (21).

9. The stainless steel thermal insulation container detection device according to claim 8, characterized in that: a plurality of rotating sleeves (31) are uniformly arranged on the periphery of the pressing cover plate (27), the rotating sleeves (31) are rotatably arranged on the fixing rod (30) through torsion springs, and two ends of the fixing rod (30) are fixedly arranged on the inner wall of the pressing cylinder (21);

a push plate (32) is fixedly mounted at the top of the rotating sleeve (31), and an arc-shaped surface (33) is formed on one side, facing the gland plate (27), of the push plate (32);

a clamping plate (34) is fixedly arranged at the bottom of the rotating sleeve (31).

10. The stainless steel thermal container detection device according to claim 9, characterized in that: the bottom of gland plate (27) is provided with support bearing (35), gland plate (27) inside center department is formed with perpendicular groove (36), the top of perpendicular groove (36) is provided with elastic hose (37), the top of elastic hose (37) extends to the outside of pressing a section of thick bamboo (21).

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