CN117360925A - A rotatory storage bin for industrial sensor installation and protection - Google Patents

Abstract

The present invention provides a rotating storage bin for industrial sensor installation and protection, which includes an interconnected connector structure and a bin structure; the bin structure includes a bin, and a substrate is provided in the bin, and the substrate can move in the bin; A turntable is provided below the base plate. The turntable is located above the inner lower surface wall of the bin. The turntable is mounted on the bin in a relatively rotating manner. The turntable is provided with a notch and the lower surface wall of the bin is provided with an extension hole. The turntable rotates , so that the notch and the extension hole partially overlap; the sensor module is fixed on the lower surface wall of the base plate; the base plate is moved so that the sensor module can extend out of the bin from the position where the notch and the extension hole overlap; the connection between the base plate and the turntable There is an opening and closing component between them, and the opening and closing component is connected to the base plate and the turntable, and is used to control the rotation of the turntable when the base plate moves. When the storage compartment is not performing data operation tasks, the opening and closing assembly can close the protruding hole in time, so that the sensor can be stored and protected in a timely manner.

Description

A rotating storage bin for industrial sensor installation and protection

Technical field

The invention belongs to the technical field of sensor storage bins, and specifically relates to a rotating storage bin used for installation and protection of industrial sensors.

Background technique

Sensor installation at industrial sites usually requires a storage environment to provide better storage and protection for sensor modules.

For example, Chinese patent publication number CN115327079A discloses a soil moisture detection device for geological exploration. The temperature and humidity sensor in the device is installed in a cylindrical storage bin structure. A long probing hole is provided at the bottom of the cylindrical storage bin. By pushing the reset component, the temperature and humidity sensor and its fixed base are pushed. The force of the spring inside the rod causes rotation, and the sensor is pushed out and retracted from the detection hole through flipping.

The above detection structure has a real-time open detection hole and lacks a structure to seal and block the detection hole. If the device is exposed to harsh environments such as moisture, high temperature, and high pressure for a long time, it will affect the reliable operation and use of the sensor. Lifespan will be adversely affected. Based on the actual working conditions and the complex external environment, the switch structure with a plugged detection hole can store the sensor in the storage bin after the sensor completes the task of collecting data, making the actual operation of the sensor safer. Therefore, this solution The aim is to propose a relatively simple rotating storage bin structure, which has a storage structure and a rotation storage and detection method. At the same time, it has a more convenient blocking structure for the detection hole, which can better realize the storage of the sensor. , protection.

Contents of the invention

The present invention is a rotating storage bin used for the installation and protection of industrial sensors, which aims to solve the problem of how to store and protect the sensors in a timely manner when the sensors are not performing data tasks.

In order to achieve the above purpose, a rotating storage bin for industrial sensor installation and protection of the present invention includes an interconnected connector structure and a bin structure; the bin structure includes a bin, and a base plate is provided in the bin. Move in the bin; a turntable is provided below the base plate, and the turntable is located above the inner lower surface wall of the bin. The turntable is relatively rotatably arranged on the bin. There is a notch on the turntable, and a protruding hole is provided on the lower surface wall of the bin. hole; the turntable rotates to partially overlap the notch and the extension hole; the sensor module is fixed on the lower surface wall of the base plate; the base plate moves so that the sensor module can extend out of the bin from the position where the notch and the extension hole overlap ; There is an opening and closing assembly between the base plate and the turntable. The opening and closing assembly is connected to the base plate and the turntable and is used to control the rotation of the turntable when the base plate moves.

Further, the opening and closing assembly includes a hinged seat, which is fixed on the lower surface wall of the base plate; a rotating rod is provided on the hinged seat, the upper end of the rotating rod is rotationally connected to the hinged seat, and the lower end of the rotating rod is connected to the upper end of the turntable. The upper surface wall of the turntable is in contact with the push plate, and the lower end of the rotating rod is in contact with the side wall of the push plate; the turntable is provided with a torsion spring, one end of the torsion spring is fixedly connected to the turntable, and the inside of the bin A sleeve is fixed on the lower surface wall, and the other end of the torsion spring is fixedly connected to the sleeve.

By arranging the opening and closing assembly, when the substrate moves down, the rotating rod forces the push plate to move, and the push plate movement causes the turntable to rotate. After the turntable rotates, the notch on the turntable will gradually coincide with the protruding hole. When the overlapping area is sufficient for the sensor module to pass through, as the substrate moves downward, the sensor module finally extends out of the bin from the overlapping position of the notch and the extension hole, and the torsion spring generates torsion. When the sensor module retracts into the storage box, the torsion force of the torsion spring recovers, the push plate reversely pushes the rotating rod back, and finally the sensor module retracts into the storage box. By continuously moving the contact point of the rotating rod against the push plate, when the sensor module passes through the overlap between the notch and the expansion hole, the overlapping area will not change, allowing the sensor module to pass smoothly.

Further, the warehouse box structure also includes a warehouse box top plate, the top of the warehouse box is open, the warehouse box top plate is at the upper end of the warehouse box, the warehouse box and the warehouse box top plate are fixedly connected by pins; the lower surface wall of the warehouse box top plate is fixed There is a casing, and the casing is in a warehouse box; the casing is provided with an internally threaded intubation tube, and the casing tube is set on the internally threaded intubation tube; the internally threaded intubation tube is movablely clamped on the casing; The lower end extends out of the casing, and the base plate is sleeved on the internal thread cannula. The base plate is fixedly connected to the internal thread cannula, and the base plate is located below the casing. The internal thread cannula is provided with a screw, and the upper end of the screw is connected to the internal thread cannula. The pipes are threaded, the lower end of the screw rod extends out of the bin, and the screw is relatively rotatably arranged on the bin.

Utilizing the rotation of the screw, the screw moves the internally threaded cannula vertically, and the vertical movement of the internally threaded cannula can also move the base plate. The movement of the substrate can be achieved by manually driving the screw to rotate, or using other driving devices (such as motors) to drive the screw to rotate. Using an electric method to drive the screw to rotate can improve the mechanization ability of the storage and installation of the sensor module.

Further, an anti-deflection slider is fixedly connected to the outer wall of the internally threaded cannula, and the anti-deflection slider is arranged along the radial direction of the internally threaded cannula; a chute is provided on the casing, and the chute is arranged along the radial direction of the internally threaded cannula. The moving direction is extended, the chute penetrates the casing along the radial direction of the casing, and the anti-deflection slider is installed in the chute.

The cooperation between the anti-deflection slider and the chute restricts the anti-deflection slider to only slide vertically, and the base plate can only move vertically. The cooperation between the anti-deflection slider and the chute makes the movement of the substrate more stable and will not cause other movements except vertical movement.

Further, the axis of the sleeve coincides with the axis of the screw, the sleeve is sleeved on the screw, and the sleeve is not in contact with the screw. The turntable is relatively rotatable on the sleeve relying on the turntable bearing, and the torsion spring is sleeved on the sleeve. superior.

The torsion spring is placed on the sleeve, so that the position of the torsion spring is not easily moved without affecting the deformation of the torsion spring due to torsion. Regardless of the torsion, the sleeve can have a limiting effect on the torsion spring. , keeping the axis of the torsion spring vertical.

Further, the connecting body structure includes a connecting body and bolts, the bolts are fixed on the upper surface wall of the connecting body, and the axis of the bolts is set vertically; the lower surface wall of the connecting body is fixedly connected to the upper surface wall of the top plate of the bin.

The existence of the connector structure allows the bin structure to be connected to the existing structure mentioned in the Chinese patent publication number CN115327079A, a soil moisture detection device for geological survey, without changing the structure of the existing technology, allowing The storage compartment of this solution can be installed in conjunction with existing technology.

Furthermore, an adjusting nut for facilitating the rotation of the screw is fixed on one end of the screw rod extending out of the bin.

By setting the adjusting nut, the rotation of the screw becomes easier, especially in the hand-driven screw rotation mode, the adjusting nut is used. Since the edge of the adjusting nut is not rounded, the raised edges can ensure the friction and allow the screw to rotate. The purpose is easier to achieve.

beneficial effects

1. By setting up the opening and closing components, the base plate can move downward, the turntable rotates, and the notch on the turntable coincides with the protruding hole on the bin. It adopts a purely mechanical mechanism, with ingenious design and simple structure.

2. By setting the opening and closing component, when the sensor component is retracted into the bin, the opening and closing component closes the protruding hole on the bin through the turntable. When the sensor component extends out of the bin, the opening and closing component allows the notch to connect with the bin. The protruding holes partially overlap to complete the storage and protection of the sensor module.

3. By setting up the opening and closing component, when the sensor component passes through the overlap of the notch and the extension hole, the overlapping area of the notch and the extension hole will not change, so that the sensor module can smoothly pass through the notch and the extension hole. The overlap of the exit holes.

Description of the drawings

Figure 1 is a cross-sectional view of the overall structure of the storage compartment when it is stored;

Figure 2 is a cross-sectional view of the overall structure of the storage compartment when in use;

Figure 3 is a positional relationship diagram of the contact point between the rotating rod and the push plate when the storage compartment is stored;

Figure 4 is a positional relationship diagram of the contact point between the rotating rod and the push plate when the storage compartment is in use;

Figure 5 is a schematic diagram of the connection position between the rotating rod and the push plate.

Reference signs: 1. Top plate of warehouse box; 2. Box; 3. Connector; 4. Bolt; 5. Casing; 6. Internally threaded intubation; 7. Anti-deflection slider; 8. Chute; 9. Screw; 10. Adjusting nut; 11. Base plate; 12. Suspension point mounting base; 13. Sensor module; 14. Sleeve; 15. Turntable; 16. Torsion spring; 17. Hinge seat; 18. Rotating rod; 19. Push plate; 20. Extrusion hole; 21. Screw bearing; 22. Turntable bearing; 23. Pin; 24. Notch.

Detailed ways

In order to make the purpose, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions of the present invention will be clearly and completely described below in conjunction with the accompanying drawings. Obviously, the described embodiments are part of the embodiments of the present invention, not all of them. Embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those of ordinary skill in the art without creative efforts fall within the scope of protection of the present invention.

See Figure 1, a rotating storage bin used for industrial sensor installation and protection, including a bin structure and a connector structure. The bin structure is used to accommodate the sensor module, and serves to house and provide a mounting position for the sensor module; the connector structure is used to fix the bin structure on the top plate of the existing device mentioned in the background art.

Specifically, the connecting body structure includes a connecting body 3 and bolts 4. The connecting body 3 has a block structure or a plate-like structure. The upper surface wall and the lower surface wall of the connecting body 3 are both arranged horizontally. The bolts 4 are fixed on the connecting body 3. At the center of the upper surface wall, the axis of the bolt 4 is arranged vertically, and the bolt 4 is cooperatively installed on the top plate of the existing device mentioned in the background art.

The warehouse box structure includes:

The top plate 1 of the warehouse box is a circular plate, which is fixed on the lower surface of the connector 3 by adhesive. The axis of the top plate 1 of the warehouse box coincides with the axis of the connector 3; a number of first screw holes are provided on the circumferential edge of the top plate. The screw holes are arranged along the radial direction of the top plate 1 of the bin;

The warehouse box 2 is cylindrical in shape with an open upper end. The warehouse box 2 is set on the top plate of the warehouse box 1 by relying on the open opening. There are a number of second screw holes on the outer circumferential wall, and the second screw holes penetrate the warehouse in the radial direction. Box 2, the second screw holes and the first screw holes are arranged in one-to-one correspondence. When installing the bin 2 and the bin top 1 together, make the axis of the second screw hole coincide with the axis of the corresponding first screw hole. The second screw hole and the first screw hole are provided with a pin 23 at the same time, and the pin 23 is threadedly connected to the first screw hole and the second screw hole at the same time to achieve the purpose of connecting the bin 2 and the bin top plate 1 together.

The sleeve 5 is fixed at the center of the lower surface wall of the top plate 1 of the warehouse box and is located in the warehouse box 2. Its axis is set vertically.

The internal threaded cannula 6 is located in the bin 2, and its axis coincides with the axis of the casing 5. The casing 5 is set on the internally threaded cannula 6, and the upper end of the internally threaded cannula 6 is movablely clamped on the casing 5. , the internally threaded cannula 6 can slide vertically relative to the casing 5. The lower end of the internally threaded cannula 6 extends out of the sleeve 5, and an anti-deflection slider 7 is fixedly connected to the outer wall of the upper end of the internally threaded cannula 6. The axis of the anti-deflection slider 7 is arranged along the radial direction of the internally threaded cannula 6. The pipe 5 is provided with a chute 8. The chute 8 extends vertically and penetrates the surface wall of the casing 5 in the radial direction of the casing 5. The anti-deflection slider 7 is penetrated in the chute 8. , the anti-deflection slider 7 can only slide vertically along the chute 8 . Limited by the anti-deflection slider 7 and the chute 8 , the internally threaded cannula 6 can only slide vertically along the casing 5 , and the internally threaded cannula 6 cannot rotate around the axis of the casing 5 . The inner wall of the internally threaded intubation tube 6 is provided with internal threads.

The axis of the screw rod 9 coincides with the axis of the internally threaded cannula 6. The upper end of the screw rod 9 is threadedly connected with the internal thread of the internally threaded cannula 6. The lower end of the screw rod 9 extends out of the bin 2. There is an opening on the bottom surface of the bin 2, and the opening runs through the bin 2 vertically. The bin 2 relies on the opening to be sleeved on the screw 9. The screw 9 is covered with a screw bearing 21, and the inner ring of the screw bearing 21 is in contact with the screw 9. The outer wall of the screw 9 is fixedly connected, and the outer ring of the screw bearing 21 is fixedly connected to the hole wall of the opening. The screw 9 relies on the screw bearing 21 to rotate around its own axis relative to the bin 2. The lower end of the screw rod 9 is fixedly connected with an adjusting nut 10 to facilitate the operator to rotate the screw rod 9 .

The base plate 11 is in the shape of a disc and is located in the bin 2. It is sleeved on the internally threaded cannula 6. The axis coincides with the axis of the internally threaded cannula 6. It is fixedly connected to the internally threaded cannula 6 and is located below the casing 5. . It moves up and down synchronously with the internally threaded cannula 6 . A plurality of hanging point mounting seats 12 are fixedly connected to the lower surface wall of the base plate 11 , and a plurality of sensor modules 13 are fixedly connected to the lower ends of the hanging point mounting seats 12 by means of bolts. When the sensor module 13 is not in use, the sensor module 13 is located in the bin 2 .

A plurality of protruding holes 20 are provided in one-to-one correspondence with the sensor modules 13 , are located directly below the corresponding sensor modules 13 , and penetrate the bin 2 vertically. When the sensor module 13 needs to be used, the sensor module 13 slides downward, and the sensor module 13 can protrude from the protrusion hole 20 .

The operator rotates the screw rod 9 forward. Since the screw rod 9 is threaded with the internally threaded cannula 6, the internally threaded cannula 6 can only move vertically, so the internally threaded cannula 6 moves downwards under the forward rotation force of the screw 9. Since the base plate 11 is fixed on the internally threaded cannula 6, the base plate 11 also moves downward. Since the hanging point mounting base 12 is fixed on the base plate 11, and the sensor module 13 is fixed on the hanging point mounting base 12, the base plate 11 moves downward. The downward movement will also drive the sensor module 13 to move downward. Finally, the sensor module 13 protrudes from the protrusion hole 20 directly below it, thereby achieving the purpose of the sensor module 13 protruding from the bin 2 . Otherwise, the screw 9 is reversed, and the sensor module 13 is retracted into the bin 2 accordingly.

It also includes an opening and closing component, which has a linkage relationship with the aforementioned bin structure. It is used to close the extension hole 20 after the sensor module 13 is retracted into the bin 2; it is also used to open the extension hole 20 when the sensor module 13 extends from the extension hole 20.

Opening and closing components include:

The sleeve 14 is in the bin 2 and is sleeved on the screw 9 without contacting the screw 9. The lower end of the sleeve 14 is fixedly connected to the inner lower surface wall of the bin 2. The upper end of the sleeve 14 is lower than the base plate 11. On the lower surface wall, the axis of the sleeve 14 coincides with the axis of the screw 9 .

The turntable 15 is sleeved on the sleeve 14 and is disc-shaped. The axis coincides with the axis of the sleeve 14. It is connected to the sleeve 5 by relying on the turntable bearing 22. The inner ring of the turntable bearing 22 is fixed to the outer wall of the sleeve 14. connection, the outer ring of the turntable bearing 22 is fixedly connected to the inner ring of the turntable 15. The turntable 15 can rotate relative to the sleeve 14 around the axis of the sleeve 14 by relying on the turntable bearing 22 . The vertical projection of the turntable 15 can cover the protruding hole 20 .

A plurality of notches 24 (see Figure 3) are opened on the turntable 15, vertically passing through the turntable 15, and corresponding to the protruding holes 20. When the forward rotation angle of the turntable 15 is X, the notches 24 are exactly in line with the corresponding holes. The overlapping area of the extending holes 20 in the vertical direction is the largest. At this time, the sensor module can extend out of the bin 2 from the overlapping area of the notch 24 and the extension hole 20 . When the turntable 15 is not rotating, other positions of the turntable 15 except the notch 24 can completely cover the protruding hole 20 . At this time, the sensor module is in the bin 2 .

The hinge seat 17 is fixed on the lower surface wall of the base plate 11 and is arranged in a position that does not interfere with the notch 24 and the sleeve 14.

The upper end of the rotating rod 18 is rotatably connected to the hinge seat 17 . The axis of the rotating shaft at the upper end of the rotating rod 18 is arranged in the horizontal direction. The lower end of the rotating rod 18 is in contact with the upper surface wall of the turntable 15 . The rotating rod 18 is arranged at an angle with the horizontal plane. Let the upper end point of the rotating rod 18 be A and the lower end point be O. A point on the straight line where the vertical plane where the rotating rod 18 is located intersects with the turntable 15 is B. The projection passes through B, and ∠AOB is an acute angle (see Figure 5).

The push plate 19 is a rectangular block. The push plate 19 is fixed on the upper surface wall of the turntable 15. The rotating rod 18 is in contact with the push plate 19. When the sensor module is in the bin 2 and is inactive (that is, in the initial position), the push plate 19 is set vertically, and the push plate 19 is perpendicular to the upper surface wall of the turntable 15 and the vertical plane where the rotating rod 18 is located.

The torsion spring 16 is sleeved on the sleeve 14, one end is fixed on the outer wall of the sleeve 14, and the other end is fixed on the upper surface wall of the turntable 15.

The sensor module extends out of the bin 2, and the action process of opening and closing the assembly is:

Initial position: The lower end of the sensor module is located at point F in the bin 2. The notch 24 on the turntable 15 will not overlap with the extension hole 20, and the extension hole 20 is completely closed.

The screw 11 is rotated manually or by other driving equipment (motor). The aforementioned base plate 11 begins to descend under the forward rotation of the screw 9. The lower end of the rotating rod 18 exerts an increasing force on the upper surface wall of the turntable 15. The force of ∠AOB The angle gradually becomes smaller. The rotating rod 18 exerts a force on the rotating disk 15 through the push plate 19 to rotate the rotating disk 15, forcing the rotating disk 15 to rotate relying on the rotating disk bearing 22. After the rotating disk 15 rotates, the friction point P between the rotating rod 18 and the pushing plate 19 will deflect. Shift (from the conflict point in Figure 3 to the conflict point in Figure 4). After the turntable 15 rotates, the torsion spring 16 deforms.

As the substrate 11 continues to descend, the turntable 15 continues to rotate. The collision point P between the rotating rod 18 and the push plate 19 is not on the surface wall of the push plate 19, but reaches the vertical edge position of the push plate 19 (i.e. the state in Figure 4). At this time, the turntable 15 rotates a total of X angle , at this time, the overlapping area of the notch 24 and the extending hole 20 in the vertical direction is the largest. At this time, the lower end of the sensor module is exactly at point G (state in Figure 1), and point G is above the turntable 15.

The base plate 11 continues to be lowered through the screw 9. Since the collision point P is always at the edge of the push plate 19, the turntable 15 no longer continues to rotate. The notch 24 and the extension hole 20 always maintain the largest overlapping area. However, the sensor module However, the group descends as the base plate 11 descends, and finally extends out of the bin 2 from the overlapping area of the notch 24 and the extension hole 20 (the state in Figure 2).

The sensor module retracts into the bin 2, and the action process of opening and closing the assembly is:

Let the screw 9 rotate in the opposite direction, and the base plate 11 will rise accordingly. The force exerted by the lower end of the rotating rod 18 on the upper surface wall of the rotating disk 15 becomes smaller and smaller, and the angle of ∠AOB gradually becomes larger. At the beginning, since the collision point P between the rotating rod 18 and the push plate 19 is on the edge of the push plate 19 (the state in Figure 4), even if the base plate 11 rises, the push plate 19 is still unable to rotate due to the rotating rod 18. That is, the turntable 15 cannot rotate, and the torsion spring 16 still maintains torsion. However, as the base plate 11 rises, the sensor module gradually retracts into the bin 2 from the overlapping area of the notch 24 and the extension hole 20 .

When the lower end of the sensor module is at point G (the state in Figure 1), the collision point P between the rotating rod 18 and the push plate 19 can still be exactly on the edge of the push plate 19 (the state in Figure 4), so the turntable 15 does not rotate. , the torsion spring 16 also continues to maintain torsion.

When the lower end of the sensor module continues to move above point G (that is, during the movement of point G to point F), the friction point P between the rotating rod 18 and the push plate 19 is transferred to the side wall of the push plate 19, and the torsion spring The torque of 16 forces the turntable 15 to rotate, and the turntable 15 gradually blocks the protruding hole 20 again; and, as the base plate 11 continues to rise, the lower end of the sensor module gradually rises from point G to point F, and the torsion spring 16 gradually returns to its original state. The torque gradually decreases. When the lower end of the sensor module is located at point F again, the torsion spring 16 loses its torque, and the turntable 15 completely blocks the extension hole 20 and returns to the initial position. The resistance point P remains in the state shown in Figure 3.

Taking the above-mentioned ideal embodiments of the present invention as inspiration and through the above description, relevant workers can make various changes and modifications without departing from the scope of the technical idea of the present invention. The technical scope of the present invention is not limited to the content in the description, and must be determined based on the scope of the claims.

Claims (7)

1. The rotary storage bin for mounting and protecting the industrial sensor is characterized by comprising a connecting body structure and a bin box structure which are connected with each other;

the bin box structure comprises a bin box, wherein a substrate is arranged in the bin box, and the substrate can move in the bin box; a rotary table is arranged below the base plate and above the lower surface wall of the inner side of the bin box, the rotary table is arranged on the bin box in a relatively rotating manner, a notch is formed in the rotary table, and an extending hole is formed in the lower surface wall of the bin box; the rotary table rotates to enable the notch to be partially overlapped with the extending hole; the sensor module is fixed on the lower surface wall of the substrate; the base plate moves to enable the sensor module to extend out of the bin box from the position where the notch coincides with the extending hole;

an opening and closing assembly is arranged between the base plate and the turntable and is connected to the base plate and the turntable and used for controlling the turntable to rotate when the base plate moves.

2. The rotary storage bin for industrial sensor installation and protection according to claim 1, wherein the opening and closing assembly comprises a hinge seat fixed on the lower surface wall of the base plate; the upper end of the rotating rod is rotatably connected to the hinging seat, and the lower end of the rotating rod is abutted against the upper surface wall of the turntable; the upper surface wall of the turntable is fixedly connected with a push plate, and the lower end of the rotating rod is abutted with the side wall of the push plate; the rotary table is provided with a torsion spring, one end of the torsion spring is fixedly connected with the rotary table, a sleeve is fixed on the lower surface wall of the inner side of the bin box, and the other end of the torsion spring is fixedly connected with the sleeve.

3. The rotary storage bin for mounting and protecting industrial sensors according to claim 2, wherein the bin box structure further comprises a bin box top plate, the upper part of the bin box is open, the bin box top plate is positioned at the upper end of the bin box, and the bin box top plate are fixedly connected through pins;

the lower surface wall of the top plate of the bin box is fixedly provided with a sleeve, and the sleeve is positioned in the bin box; the sleeve is provided with an internal thread insertion pipe, the sleeve is sleeved on the internal thread insertion pipe, the internal thread insertion pipe is movably clamped on the sleeve, the lower end of the internal thread insertion pipe extends out of the sleeve, the base plate is sleeved on the internal thread insertion pipe and fixedly connected with the internal thread insertion pipe, and the base plate is positioned below the sleeve; the screw rod is arranged on the internal thread insertion pipe, the upper end of the screw rod is in threaded connection with the internal thread insertion pipe, the lower end of the screw rod extends out of the bin box, and the screw rod is arranged on the bin box in a relative rotation mode.

4. The rotary storage bin for mounting and protecting an industrial sensor according to claim 3, wherein the outer wall of the internal thread insertion tube is fixedly connected with an anti-deflection sliding block, and the anti-deflection sliding block is arranged along the radial direction of the internal thread insertion tube; a sliding groove is formed in the sleeve, the sliding groove extends along the moving direction of the internal thread insertion pipe, the sliding groove penetrates through the sleeve in the radial direction of the sleeve, and the anti-deflection sliding block penetrates through the sliding groove.

5. A rotary storage bin for mounting and protecting an industrial sensor according to claim 3, wherein the axis of the sleeve coincides with the axis of the screw, the sleeve is sleeved on the screw, the sleeve is not in contact with the screw, the turntable is arranged on the sleeve in a relatively rotating manner by means of a turntable bearing, and the torsion spring is sleeved on the sleeve.

6. A rotary storage bin for industrial sensor installation and protection according to claim 3, wherein the connector structure comprises a connector and a bolt, the bolt is fixed on the upper surface wall of the connector, and the axis of the bolt is vertically arranged; the lower surface wall of the connecting body is fixedly connected with the upper surface wall of the top plate of the bin box.

7. A rotary storage bin for industrial sensor installation and protection according to claim 3, wherein an end of the screw extending out of the bin is fixed with an adjusting nut for facilitating rotation of the screw.