CN111964626A - High-temperature thickness measuring system for pressure container - Google Patents

Abstract

The invention belongs to the technical field of container thickness measurement, in particular to a high-temperature thickness measurement system for a pressure container, which aims at solving the problems that the existing thickness gauge is generally a split type thickness gauge or a fixed type thickness gauge, the structural form is single, a detection head cannot be remotely separated from a thickness gauge body for measurement, and the use is inconvenient, it includes the base, and the bottom of base is seted up there is the end mouth groove, and fixed mounting has four perpendicular poles on the top inner wall in end mouth groove, and slidable mounting has same lifter plate on four perpendicular poles, and the bottom of lifter plate is connected with four gyro wheels, a plurality of reset spring of fixedly connected with between the top of lifter plate and the top inner wall in end mouth groove, and the top of base is rotated and is connected with the cylinder, and the top fixedly connected with rotary power structure of base, cylinder and rotary power structural connection, the lift groove has been seted up at the cylindrical top. The invention has convenient operation, can meet the requirements of measuring different positions, angles and distances, can be conveniently moved and has flexible use.

Description

High-temperature thickness measuring system for pressure container

Technical Field

The invention belongs to the technical field of container thickness measurement, and particularly relates to a high-temperature thickness measurement system for a pressure container.

Background

The thickness gauge is used for measuring the thickness of various materials, objects and various processing parts, also can monitor various pipelines and pressure vessels in the production equipment, monitors the reduction degree of the corroded materials and pressure vessels in the use process, is widely applied to various fields such as petroleum, chemical industry, metallurgy, shipbuilding, aviation, aerospace and the like, requires extremely high accuracy, often cannot be detected through manual work when detecting the pressure vessels, and the pressure vessels have high temperature, so that the danger is easily caused by manual thickness measurement.

The existing thickness gauge is generally a split type thickness gauge or a fixed type thickness gauge, the structural form is single, a detection head cannot leave a thickness gauge body remotely for measurement, and the use is inconvenient.

Disclosure of Invention

The invention aims to solve the defects that the conventional thickness gauge is generally a split type thickness gauge or a fixed type thickness gauge and has a single structural form, a detection head cannot be far away from a thickness gauge body to measure, and the use is inconvenient.

In order to achieve the purpose, the invention adopts the following technical scheme:

a high-temperature thickness measuring system for a pressure container comprises a base, wherein a bottom opening groove is formed in the bottom of the base, four vertical rods are fixedly mounted on the inner wall of the top of the bottom opening groove, a same lifting plate is slidably mounted on the four vertical rods, four idler wheels are connected to the bottom of the lifting plate, a plurality of reset springs are fixedly connected between the top of the lifting plate and the inner wall of the top of the bottom opening groove, a cylinder is rotatably connected to the top of the base, a rotary power structure is fixedly connected to the top of the base and connected with the rotary power structure, a lifting groove is formed in the top of the cylinder, a lifting rod is vertically slidably mounted in the lifting groove, a movable hole is formed in the top of the base and movably connected with the movable hole, a worm motor is arranged on the outer side of the cylinder and connected with the lifting rod, a transmission motor is arranged on the top of the, the transverse groove has been seted up to the bottom of transverse plate, lifter and transverse groove sliding connection, the top of lifter is provided with drive motor, fixed mounting has drive gear on drive motor's the output shaft, fixed mounting has the drive rack on one side inner wall of transverse groove, drive gear meshes with the drive rack mutually, the bottom of transverse plate is seted up flutedly, slidable mounting has two meshing racks in the recess, equal fixed mounting has the grip block on two meshing racks, be provided with the regulation drive structure in the recess, it is connected with two meshing racks to adjust the drive structure, be provided with probe sensor on the grip block in two grip blocks.

Preferably, the adjusting and driving structure comprises a clamping motor and an engaging gear, the clamping motor is fixedly mounted on the inner wall of the top of the groove, the engaging gear is fixedly mounted on an output shaft of the clamping motor, and the two engaging racks are engaged with the engaging gear.

Preferably, the inner walls of the two sides of the groove are fixedly provided with supporting rods, one side, away from each other, of each of the two meshing racks is provided with a supporting groove, and the two supporting rods are respectively connected with the two supporting grooves in a sliding manner.

Preferably, guide rods are fixedly mounted on the inner walls of the two sides of the transverse groove, guide rod grooves are formed in the two sides of the lifting rod, and the two guide rods are connected with the two guide rod grooves in a sliding mode respectively.

Preferably, the holding tank has been seted up at the top of lifter, and drive motor fixed connection is in the holding tank.

Preferably, the rotary power structure comprises a motor, a gear and an annular outer gear, the motor is fixedly connected to the top of the base, the gear is fixedly mounted on an output shaft of the motor, the annular outer gear is fixedly sleeved on the outer side of the cylinder, and the gear is meshed with the annular outer gear.

Preferably, the top of the base is fixedly provided with an annular ring, the outer side of the cylinder is fixedly provided with a support ring, the inner side of the annular ring is provided with an annular groove, and the support ring is in sliding connection with the annular groove.

Preferably, a rack groove is formed in the left side of the lifting rod, a rack is fixedly mounted on the inner wall of the rack groove, and a driving gear is fixedly mounted on an output shaft of the worm motor and meshed with the rack.

Preferably, the top fixedly connected with block terminal of base, the top of block terminal is connected with the controller.

Preferably, the top of the base is obliquely provided with a push handle, the inner wall of the top of the bottom opening groove is fixedly connected with a plurality of elastic pads, and the lifting plate is in contact with the elastic pads.

Compared with the prior art, the invention has the advantages that:

(1) this scheme worm motor drive driving gear rotates, drives the gear and drives the lifter through the rack and carry out altitude mixture control, and the lifter drives the transverse plate and goes up and down, and the transverse plate drives two grip blocks and goes up and down, can satisfy different high user demand.

(2) The transmission motor drives the transmission rack to move through the transmission gear, the transmission rack drives the transverse plate to carry out horizontal adjustment, and the transverse plate drives the two clamping plates to carry out horizontal adjustment, so that the two clamping plates are close to the container and can be used for remote thickness measurement.

(3) Make two grip blocks be located the limit mouth both sides of two containers respectively, the centre gripping motor drives meshing gear revolve, and meshing gear drives two meshing racks and is close to each other, and two meshing racks drive two grip blocks and are close to each other and carry out the centre gripping to the container, can detect the interval of two grip blocks through probe sensor, and then detect the thickness of container.

(4) The motor can drive the rotation of annular external gear through the gear, and annular external gear can drive cylinder, horizontal board and two grip blocks rotatory, angle when can adjusting the thickness measurement, after the measurement is accomplished, resets two grip blocks for the lifter downstream extrudees the lifter plate, and the lifter plate drives four gyro wheels downstream and ground contact, can conveniently remove, uses in a flexible way.

The invention has convenient operation, can meet the requirements of measuring different positions, angles and distances, can be conveniently moved and has flexible use.

Drawings

FIG. 1 is a schematic structural diagram of a high-temperature thickness measuring system for a pressure vessel according to the present invention;

FIG. 2 is a schematic structural diagram of a portion A of a high-temperature thickness measurement system for a pressure vessel according to the present invention;

FIG. 3 is a schematic perspective view of a cylinder and a lifting rod of the high temperature thickness measuring system for pressure vessels according to the present invention;

FIG. 4 is a schematic structural diagram of a portion B of a high-temperature thickness measurement system for a pressure vessel according to the present invention;

FIG. 5 is a schematic structural diagram of a portion C of a high-temperature thickness measuring system for a pressure vessel according to the present invention;

fig. 6 is a schematic top view of the meshing gear, the meshing rack and the clamping plate of the high-temperature thickness measuring system for the pressure vessel according to the present invention.

In the figure: 1. a base; 2. a bottom opening groove; 3. a vertical rod; 4. a lifting plate; 5. a roller; 6. a return spring; 7. a cylinder; 8. an annular ring; 9. a support ring; 10. an annular groove; 11. a motor; 12. a gear; 13. an annular outer gear; 14. a lifting rod; 15. a lifting groove; 16. a rack slot; 17. a rack; 18. a movable hole; 19. a worm motor; 20. driving the gear; 21. a controller; 22. a transverse plate; 23. a guide bar; 24. a drive rack; 25. a drive motor; 26. a guide bar groove; 27. a transverse slot; 28. a transmission gear; 29. a clamping plate; 30. a groove; 31. a clamping motor; 32. a probe sensor; 33. a meshing gear; 34. meshing the racks; 35. a support bar; 36. a support groove; 37. accommodating grooves; 38. a push handle; 39. a distribution box; 40. an elastic pad.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Example one

Referring to fig. 1-6, a high temperature thickness measuring system for pressure vessels comprises a base 1, a bottom slot 2 is arranged at the bottom of the base 1, four vertical rods 3 are fixedly arranged on the inner wall of the top of the bottom slot 2, the same lifting plate 4 is slidably arranged on the four vertical rods 3, four rollers 5 are connected with the bottom of the lifting plate 4, a plurality of reset springs 6 are fixedly connected between the top of the lifting plate 4 and the inner wall of the top of the bottom slot 2, a cylinder 7 is rotatably connected with the top of the base 1, a rotary power structure is fixedly connected with the top of the base 1, the cylinder 7 is connected with the rotary power structure, a lifting slot 15 is arranged at the top of the cylinder 7, a lifting rod 14 is vertically slidably arranged in the lifting slot 15, a movable hole 18 is arranged at the top of the base 1, the lifting rod 14 is movably connected with the movable hole 18, a motor worm 19 is arranged on the outer side of the cylinder, the top of lifter 14 is provided with drive motor 25, the top sliding connection of lifter 14 has transverse plate 22, transverse groove 27 has been seted up to transverse plate 22's bottom, lifter 14 and transverse groove 27 sliding connection, lifter 14's top is provided with drive motor 25, fixed mounting has drive gear 28 on drive motor 25's the output shaft, fixed mounting has drive rack 24 on one side inner wall of transverse groove 27, drive gear 28 meshes with drive rack 24 mutually, recess 30 has been seted up to transverse plate 22's bottom, slidable mounting has two meshing racks 34 in the recess 30, equal fixed mounting has grip block 29 on two meshing racks 34, be provided with the regulation drive structure in the recess 30, the regulation drive structure is connected with two meshing racks 34, be provided with probe sensor 32 on one grip block 29 in two grip blocks 29.

In this embodiment, the adjusting and driving structure includes a clamping motor 31 and a meshing gear 33, the clamping motor 31 is fixedly mounted on the inner wall of the top of the groove 30, the meshing gear 33 is fixedly mounted on the output shaft of the clamping motor 31, and the two meshing racks 34 are meshed with the meshing gear 33.

In this embodiment, equal fixed mounting has the bracing piece 35 on the both sides inner wall of recess 30, and two meshing rack 34 one side of keeping away from each other has all seted up and has supported groove 36, and two bracing pieces 35 respectively with two 36 sliding connection that support grooves, bracing piece 35 and the cooperation of supporting groove 36 can make meshing rack 34 only slide in recess 30.

In this embodiment, all fixed mounting has guide arm 23 on the both sides inner wall of transverse groove 27, and guide bar groove 26 has all been seted up to the both sides of lifter 14, and two guide arms 23 respectively with two guide bar grooves 26 sliding connection, guide arm 23 and the cooperation of guide bar groove 26 can make lifter 14 can not break away from with transverse groove 27.

In this embodiment, accommodation groove 37 has been seted up at the top of lifter 14, and drive motor 25 fixed connection is in accommodation groove 37.

In this embodiment, the rotating power structure includes a motor 11, a gear 12 and an external annular gear 13, the motor 11 is fixedly connected to the top of the base 1, the gear 12 is fixedly installed on an output shaft of the motor 11, the external annular gear 13 is fixedly sleeved on the outer side of the cylinder 7, and the gear 12 is engaged with the external annular gear 13.

In this embodiment, the top fixed mounting of base 1 has annular ring 8, and the outside fixed mounting of cylinder 7 has support ring 9, and annular groove 10 has been seted up to annular ring 8's inboard, and support ring 9 and annular groove 10 sliding connection, support ring 9 slide in annular groove 10 can play the supporting role when cylinder 7 is rotatory.

In this embodiment, a rack slot 16 is formed in the left side of the lifting rod 14, a rack 17 is fixedly mounted on the inner wall of the rack slot 16, and a driving gear 20 is fixedly mounted on an output shaft of the worm motor 19, and the driving gear 20 is engaged with the rack 17.

In this embodiment, the top fixedly connected with block terminal 39 of base 1, the top of block terminal 39 is connected with controller 21, is provided with the power in the block terminal 39.

In this embodiment, the top of base 1 is provided with the slope and pushes away handle 38, and a plurality of cushion 40 of fixedly connected with on the top inner wall of end opening groove 2, lifter plate 4 and cushion 40 contact, and elastic belt you 40 can play the supporting role to lifter plate 4.

Example two

Referring to fig. 1-6, a high temperature thickness measuring system for pressure vessels comprises a base 1, a bottom slot 2 is arranged at the bottom of the base 1, four vertical rods 3 are fixedly arranged on the inner wall of the top of the bottom slot 2 by welding, the same lifting plate 4 is slidably arranged on the four vertical rods 3, four rollers 5 are connected with the bottom of the lifting plate 4, a plurality of reset springs 6 are fixedly connected between the top of the lifting plate 4 and the inner wall of the top of the bottom slot 2 by screws, a cylinder 7 is rotatably connected with the top of the base 1, a rotary power structure is fixedly connected with the top of the base 1 by screws, the cylinder 7 is connected with the rotary power structure, a lifting slot 15 is arranged at the top of the cylinder 7, a lifting rod 14 is vertically slidably arranged in the lifting slot 15, a movable hole 18 is arranged at the top of the base 1, the lifting rod 14 is movably connected with the movable hole 18, a worm 19 is, the worm motor 19 is connected with the lifting rod 14, a transmission motor 25 is arranged at the top of the lifting rod 14, a transverse plate 22 is connected to the top of the lifting rod 14 in a sliding mode, a transverse groove 27 is formed in the bottom of the transverse plate 22, the lifting rod 14 is connected with the transverse groove 27 in a sliding mode, the transmission motor 25 is arranged at the top of the lifting rod 14, a transmission gear 28 is fixedly installed on an output shaft of the transmission motor 25 through welding, a transmission rack 24 is installed on the inner wall of one side of the transverse groove 27 through welding, the transmission gear 28 is meshed with the transmission rack 24, a groove 30 is formed in the bottom of the transverse plate 22, two meshing racks 34 are installed in the groove 30 in a sliding mode, clamping plates 29 are installed on the two meshing racks 34 through welding, an adjusting driving structure is arranged in the groove 30 and connected with the two meshing racks 34, and a probe sensor 32 is arranged.

In this embodiment, the adjusting and driving structure includes a clamping motor 31 and an engaging gear 33, the clamping motor 31 is fixedly mounted on the inner wall of the top of the groove 30 by welding, the engaging gear 33 is fixedly mounted on the output shaft of the clamping motor 31 by welding, and the two engaging racks 34 are engaged with the engaging gear 33.

In this embodiment, all there is the bracing piece 35 through welded fastening on the both sides inner wall of recess 30, and support groove 36 has all been seted up to one side that two meshing racks 34 kept away from each other, and two bracing pieces 35 respectively with two support groove 36 sliding connection, bracing piece 35 and the cooperation of support groove 36 can be so that meshing rack 34 can only slide in recess 30.

In this embodiment, all there is guide rod 23 through welded fastening on the both sides inner wall of transverse groove 27, and guide rod groove 26 has all been seted up to the both sides of lifter 14, and two guide rods 23 respectively with two guide rod grooves 26 sliding connection, guide rod 23 and the cooperation of guide rod groove 26 can make lifter 14 can not break away from with transverse groove 27.

In this embodiment, accommodation groove 37 has been seted up at the top of lifter 14, and drive motor 25 passes through screw fixed connection in accommodation groove 37.

In this embodiment, the rotary power structure includes a motor 11, a gear 12 and an external annular gear 13, the motor 11 is fixedly connected to the top of the base 1 through screws, the gear 12 is fixedly mounted on an output shaft of the motor 11 through welding, the external annular gear 13 is fixedly sleeved on the outer side of the cylinder 7, and the gear 12 is engaged with the external annular gear 13.

In this embodiment, the top of base 1 has annular ring 8 through welded fastening installation, and welded fastening installation has support ring 9 in the outside of cylinder 7, and annular ring 10 has been seted up to annular ring 8's inboard, and support ring 9 and annular ring 10 sliding connection, support ring 9 slide in annular ring 10 can play the supporting role when cylinder 7 is rotatory.

In this embodiment, a rack groove 16 is formed in the left side of the lifting rod 14, a rack 17 is fixedly welded to the inner wall of the rack groove 16, and a driving gear 20 is fixedly welded to the output shaft of the worm motor 19 and meshes with the rack 17, so that the driving gear 20 is engaged with the rack 17.

In this embodiment, screw fixedly connected with block terminal 39 is passed through at the top of base 1, and the top of block terminal 39 is connected with controller 21, is provided with the power in the block terminal 39.

In this embodiment, the top of base 1 is provided with the slope and pushes away handle 38, through a plurality of cushion 40 of screw fixed connection on the top inner wall of end opening groove 2, lifter plate 4 and cushion 40 contact, and elastic band you 40 can play the supporting role to lifter plate 4.

In the embodiment, when the device is used, the electrical equipment is powered on and the controller 21 is powered on, the worm motor 19 drives the gear 20 to rotate, the gear 20 drives the lifting rod 14 to perform height adjustment through the rack 17, the lifting rod 14 drives the transverse plate 22 to lift, the transverse plate 22 drives the two clamping plates 29 to lift, so that the device can meet different height use requirements, the transmission motor 25 drives the transmission gear 28 to rotate, the transmission gear 28 drives the transmission rack 24 to move, the transmission rack 24 drives the transverse plate 22 to perform horizontal adjustment, the transverse plate 22 drives the two clamping plates 29 to perform horizontal adjustment, so that the two clamping plates 29 are close to the container and can be used for remote thickness measurement, the two clamping plates 29 are respectively positioned at two sides of the rim of the two containers, the clamping motor 31 is started, the clamping motor 31 drives the meshing gear 33 to rotate, the meshing gear 33 drives the two meshing racks 34 to, two meshing racks 34 drive two grip blocks 29 and are close to each other and carry out the centre gripping to the container, can detect the interval of two grip blocks 29 through probe sensor 32, and then detect the thickness of container, motor 11 can drive annular external gear 13 through gear 12 and rotate, annular external gear 13 can drive cylinder 7, transverse plate 22 and two grip blocks 29 are rotatory, angle when can adjusting the thickness measurement, after the measurement is accomplished, reset two grip blocks 29, make lifter 14 downstream extrusion lifter plate 4, lifter plate 4 drives four gyro wheels 5 downstream and ground contact, can conveniently remove, and flexible in use.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims (10)

1. A high-temperature thickness measuring system for a pressure container comprises a base (1), wherein a bottom groove (2) is formed in the bottom of the base (1), and is characterized in that four vertical rods (3) are fixedly installed on the inner wall of the top of the bottom groove (2), a same lifting plate (4) is installed on the four vertical rods (3) in a sliding manner, four idler wheels (5) are connected to the bottom of the lifting plate (4), a plurality of reset springs (6) are fixedly connected between the top of the lifting plate (4) and the inner wall of the top of the bottom groove (2), a cylinder (7) is rotatably connected to the top of the base (1), a rotary power structure is fixedly connected to the top of the base (1), the cylinder (7) is connected with a rotary power structure, a lifting groove (15) is formed in the top of the cylinder (7), a lifting rod (14) is vertically installed in the lifting groove (15) in a sliding manner, a movable hole (18) is formed, the lifting rod (14) is movably connected with the movable hole (18), a worm motor (19) is arranged on the outer side of the cylinder (7), the worm motor (19) is connected with the lifting rod (14), a transmission motor (25) is arranged on the top of the lifting rod (14), a transverse plate (22) is slidably connected with the top of the lifting rod (14), a transverse groove (27) is formed in the bottom of the transverse plate (22), the lifting rod (14) is slidably connected with the transverse groove (27), the transmission motor (25) is arranged on the top of the lifting rod (14), a transmission gear (28) is fixedly installed on an output shaft of the transmission motor (25), a transmission rack (24) is fixedly installed on the inner wall of one side of the transverse groove (27), the transmission gear (28) is meshed with the transmission rack (24), a groove (30) is formed in the bottom of the transverse plate (22), two meshing racks (34) are slidably installed in the, clamping plates (29) are fixedly mounted on the two meshing racks (34), an adjusting driving structure is arranged in the groove (30), the adjusting driving structure is connected with the two meshing racks (34), and a probe sensor (32) is arranged on one clamping plate (29) of the two clamping plates (29).

2. The system for measuring the thickness of the pressure vessel at high temperature as claimed in claim 1, wherein the adjusting and driving structure comprises a clamping motor (31) and an engaging gear (33), the clamping motor (31) is fixedly installed on the inner wall of the top of the groove (30), the engaging gear (33) is fixedly installed on the output shaft of the clamping motor (31), and the two engaging racks (34) are engaged with the engaging gear (33).

3. The high-temperature thickness measuring system for the pressure vessel as claimed in claim 1, wherein the inner walls of the two sides of the groove (30) are fixedly provided with support rods (35), the side of the two meshing racks (34) away from each other is provided with a support groove (36), and the two support rods (35) are respectively connected with the two support grooves (36) in a sliding manner.

4. The high-temperature thickness measuring system for the pressure vessel as claimed in claim 1, wherein guide rods (23) are fixedly mounted on inner walls of two sides of the transverse groove (27), guide rod grooves (26) are formed in two sides of the lifting rod (14), and the two guide rods (23) are respectively connected with the two guide rod grooves (26) in a sliding manner.

5. The high-temperature thickness measuring system for the pressure vessel as claimed in claim 1, wherein a receiving groove (37) is formed at the top of the lifting rod (14), and the transmission motor (25) is fixedly connected in the receiving groove (37).

6. The high-temperature thickness measuring system for the pressure vessel is characterized in that the rotary power structure comprises a motor (11), a gear (12) and an external annular gear (13), the motor (11) is fixedly connected to the top of the base (1), the gear (12) is fixedly installed on an output shaft of the motor (11), the external annular gear (13) is fixedly sleeved on the outer side of the cylinder (7), and the gear (12) is meshed with the external annular gear (13).

7. The high-temperature thickness measuring system for the pressure vessel as claimed in claim 1, wherein an annular ring (8) is fixedly mounted at the top of the base (1), a support ring (9) is fixedly mounted at the outer side of the cylinder (7), an annular groove (10) is formed in the inner side of the annular ring (8), and the support ring (9) is slidably connected with the annular groove (10).

8. The high-temperature thickness measuring system for the pressure vessel as claimed in claim 1, wherein a rack groove (16) is formed in the left side of the lifting rod (14), a rack (17) is fixedly installed on the inner wall of the rack groove (16), a driving gear (20) is fixedly installed on an output shaft of the worm motor (19), and the driving gear (20) is meshed with the rack (17).

9. The high-temperature thickness measuring system for the pressure vessel is characterized in that a distribution box (39) is fixedly connected to the top of the base (1), and a controller (21) is connected to the top of the distribution box (39).

10. The high-temperature thickness measuring system for the pressure vessel is characterized in that a push handle (38) is obliquely arranged at the top of the base (1), a plurality of elastic pads (40) are fixedly connected to the inner wall of the top of the bottom opening groove (2), and the lifting plate (4) is in contact with the elastic pads (40).

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