CN115508272A - Concrete member corrosion detection equipment - Google Patents

Abstract

A kind of concrete member corrodes the check out test set, including servomotor, air cylinder and chassis; the air pump is vertically installed in the center ring at chassis up end center, the air feed port of air pump bottom stretches out and dock along the center ring and pneumatic component's cylinder air feed, the vertical telescopic link of installing of air pump top platform, the ring frame is installed to telescopic link top cover axle outer lane, six groups of extending arm are equipped with to the frame in the clearance of ring frame inner circle face, servo motor is installed through the shackle in the terminal pilot hole of extending arm, the first section transmission butt joint of the transmission port of servo motor bottom and the butt joint end at the top at detection section of thick bamboo top, the butt joint dish on butt joint bottom shaft and the pneumatic component of detection section of thick bamboo bottom. The concrete member corrosion detection equipment is adaptive to different geological detection, pH value and water supply detection and different installation angle detection through environment simulation, and can be matched with a plurality of groups of concrete members to independently detect simultaneously.

Description

Concrete member corrosion detection equipment

Technical Field

The invention belongs to the technical field of material detection equipment, and particularly relates to concrete member corrosion detection equipment.

Background

The concrete member plays a role in supporting and protecting equipment in work, production and construction; in the practical process of concrete construction as a foundation, the concrete needs to have a certain degree of corrosion resistance, so that mixed metal components in the concrete construction need to pass a corrosion resistance detection experiment before being put into production and use.

Disclosure of Invention

In order to solve the problems, the invention discloses a concrete member corrosion detection device which can adapt to different geological detections, pH value and water supply detections, different installation angle detections and can be matched with a plurality of groups of concrete members to simultaneously and independently detect.

In order to achieve the purpose, the technical scheme of the invention is as follows:

a kind of concrete member corrodes the check out test set, including servomotor, air cylinder and chassis; the air pump is vertically installed in the center ring at chassis up end center, the air feed port of air pump bottom stretches out and dock along the center ring and pneumatic component's cylinder air feed, the vertical telescopic link of installing of air pump top platform, the ring frame is installed to telescopic link top cover axle outer lane, six groups of extending arm are equipped with to the frame in the clearance of ring frame inner circle face, servo motor is installed through the shackle in the terminal pilot hole of extending arm, the first section transmission butt joint of the transmission port of servo motor bottom and the butt joint end at the top at detection section of thick bamboo top, the butt joint dish on butt joint bottom shaft and the pneumatic component of detection section of thick bamboo bottom.

Further, the detection cylinder comprises a temperature control separation cylinder, the outer wall of the temperature control separation cylinder is integrally packaged with a hollow shell, a cavity is reserved between the outer wall of the temperature control separation cylinder and the hollow shell, and a valve port installed in the middle section of the hollow shell is in selective air supply butt joint with an external pipeline.

Furthermore, the upper end and the lower end of the temperature control partition cylinder are respectively provided with an upper ring buckle and a lower ring buckle, the caliber of the lower ring buckle is smaller than that of the upper ring buckle, and a flow guide column and a filling column are respectively inserted into the upper ring buckle and the lower ring buckle along the inlet; the flow guide column comprises a butt joint end and a drainage sleeve, the end part of the upper half section of the butt joint end is in butt joint with a transmission port at the bottom of the servo motor, four groups of infusion ports are horizontally distributed at the end part of the lower half section of the butt joint end, liquid input by the four groups of infusion ports extends to the inner wall of the drainage sleeve, and the inner wall of the drainage sleeve is corrugated.

Furthermore, the bottom tube wall of the drainage sleeve is of a smooth barreled structure, the bottom tube wall of the drainage sleeve is in clearance fit with the outer wall of the filling column, and the integrated extended friction ring sleeve on the bottom tube wall of the drainage sleeve is in friction contact with the inner wall of the detection cylinder.

Furthermore, the packed column comprises a packing sleeve, an experiment inner cylinder, packing blocks and inner ribs, wherein the experiment inner cylinder is of a two-group semi-arc cylinder wall structure, the two groups of experiment inner cylinders are installed inside the packing sleeve in a closed butt joint state, a plurality of groups of inner ribs are uniformly distributed on the inner wall of the experiment inner cylinder, and the extension end parts of the inner ribs are in limit contact with the packing blocks filled inside the experiment inner cylinder; the pneumatic component is characterized in that a butt joint bottom shaft is installed at the bottom of the filling sleeve, the top of the butt joint bottom shaft is of a plane supporting platform structure, a platform at the top of the butt joint bottom shaft and the filling sleeve are of a sealed butt joint structure, the bottom of the butt joint bottom shaft is of a hemispherical cambered surface structure, and the end head at the bottom of the butt joint bottom shaft and a butt joint disc on the pneumatic component are of a push support structure.

Furthermore, concrete component sections are selectively inserted into the filling blocks in the filling sleeves, the concrete component sections are cylindrical, binding grooves formed in the tops of the concrete component sections are welded with integrally extended ends at the bottoms of the sealing covers, outer rings of the sealing covers and annular ribs are in clamping connection, and the annular ribs are integrally connected to the upper half ends of the inner walls of the butt joint ends.

Furthermore, the pneumatic assembly comprises a cylinder, a movable groove and an air pump; the cylinder passes through the pipeline and butts with the air pump air feed, the cylinder is evenly dispersed state water tiling dress section on the chassis along the centre ring, cylinder drive end stretches out and with butt joint dish synchronous connection along the movable groove direction, butt joint dish assembly port up and with butt joint bottom shaft be ejection bearing structure.

The beneficial effects of the invention are as follows:

compared with the prior art, the invention adopts an experimental structure that a plurality of groups of detection cylinders detect simultaneously, and can carry out preliminary detection procedures of different geologies in real time by utilizing the concrete members which are adaptively cut and intercepted by adding different filling blocks, thereby solving the technical problem that single detection equipment cannot complete corrosion resistance detection procedures of different geologies in a unified experimental cavity; meanwhile, detection aqueous solutions with different pH values are added in necessary detection time periods, so that an experiment that concrete members are corroded by the different pH value solutions brought to the ground in the precipitation process can be simulated; meanwhile, the adjustment of various angles can adapt to corrosion resistance tests of corroded concrete members with various assembly styles and assembly angles.

Drawings

FIG. 1 is an exploded view of a concrete member corrosion detecting apparatus detecting cylinder according to the present invention.

Fig. 2 is a schematic structural view of a guide column of the concrete member corrosion detection apparatus of the present invention.

FIG. 3 is a top view of a packed column of a concrete member corrosion detection device of the present invention.

FIG. 4 is a schematic view of a driving butt joint partial structure of the detection cylinder of the concrete member corrosion detection device of the present invention.

FIG. 5 is a cross-sectional view of the butt end of the corrosion detecting apparatus for concrete member according to the present invention.

FIG. 6 is a front view of a top bracket of the corrosion detection device for a concrete member according to the present invention.

FIG. 7 is a schematic structural diagram of a concrete member corrosion detection apparatus chassis according to the present invention.

List of reference symbols:

the device comprises a detection cylinder 1, a servo motor 2, a sealing cover 3, a butt joint end 4, a drainage sleeve 5, a sealing ring 6, a temperature control separation cylinder 7, a lower buckle 8, a filling sleeve 9, a butt joint bottom shaft 10, an upper buckle 12, a transfusion port 13, a filling block 14, an experiment inner cylinder 15, an inner rib 16, an assembly hole 17, a friction ring sleeve 18, an annular rib 19, a sleeve shaft 20, an annular frame 21, an extension arm 22, a telescopic rod 23, an air pump 24, a central ring 25, a chassis 26, an air cylinder 27, a movable groove 28 and a butt joint disk 29.

Detailed Description

The present invention will be further illustrated with reference to the accompanying drawings and specific embodiments, which are to be understood as merely illustrative of the invention and not as limiting the scope of the invention.

As shown in fig. 1, 2, 4, 6 and 7, a concrete member corrosion detecting apparatus includes a servo motor, a cylinder, and a chassis; the utility model discloses a pneumatic detection device, including chassis 26, air pump 24, telescopic link 23, ring frame 21, servo motor 2, transmission port and the butt joint disk 29 on the butt joint end 4 at the top of detection section of thick bamboo 1 top, the vertical air pump 24 that installs in the centre ring 25 at chassis 26 up end center, the air feed port of air pump 24 bottom stretches out and docks along centre ring 25 and with pneumatic component's cylinder 27 air feed, the vertical telescopic link 23 of installing of air pump 24 top platform, the ring frame 21 is installed to telescopic link 23 top sleeve spindle 20 outer lane, the clearance inner tower of ring frame 21 inner tower is equipped with six extension arm 22 of group, servo motor 2 is installed through the shackle to extension arm 22 terminal pilot hole 17, the transmission port of servo motor 2 bottom docks with the butt joint end 4 first section transmission at the top of detection section of thick bamboo 1 top, the butt joint end axle 10 of detection section of 1 bottom and the butt joint disk 29 on the pneumatic component. The invention relates to vertical concrete member detection equipment, wherein detection time is required to be completed through linkage and matching of an air pump 24 and an air cylinder 27 in the detection process. The staff will realize that the part axle dress concrete member of intercepting from top to bottom implants the detection section of thick bamboo 1 inside. In the detection process, the servo motor 2 can control the detection cylinder 1 to do axis rotation motion through rated rotation speed and rotation period; the effect of the movement is to uniformly fill the filling blocks in the detection cylinder 1, so that the condition that the filling blocks are large in area and overhead is avoided, and the subsequent experiment efficiency of inputting water or solution with different pH values is improved. The pneumatic equipment adopted in the invention inputs required high-pressure gas in real time through the air pump 24 to drive the driving end of the air cylinder 27 and the butt plate 29 to drive the detection cylinder 1 to do gradual inclined motion, and in the inclined process, the solution or the filling block is influenced by gravity, so that the local part of the concrete member segment in the detection cylinder 1 can be corroded more effectively, and the targeted corrosion resistance detection effect is achieved. During the tilting of the detection cylinder 1, the extending arm 22 on the ring frame 21 will have a driven effect, and the extending or retracting action is completed. Of course, the telescopic rod 23 can also adjust the height driven adjustment process when the angle of the detection cylinder 1 changes.

As shown in fig. 1 and 4, the detection cylinder 1 includes a temperature control isolation cylinder 7, a hollow shell is integrally packaged on the outer wall of the temperature control isolation cylinder 7, a cavity is left between the outer wall of the temperature control isolation cylinder 7 and the hollow shell, and a valve port installed in the middle section of the hollow shell is in selective air supply butt joint with an external pipeline. Wherein, the cavity between the temperature control separation cylinder 7 and the shell can discharge heat supply or temperature reduction steam and gas inwards or outwards through the valve port, thereby playing the effect of temperature control. The method is used for simulating the corrosion resistance experiment of the concrete member influenced by the geological change due to the climate change.

As shown in fig. 1, fig. 2, fig. 4 and fig. 5, an upper buckle 12 and a lower buckle 8 are respectively disposed at the upper end and the lower end of the temperature control partition 7, the aperture of the lower buckle 8 is smaller than that of the upper buckle 12, and a flow guide column and a filling column are respectively inserted into the upper buckle 12 and the lower buckle 8 along the inlet; the flow guide column comprises a butt joint end 4 and a drainage sleeve 5, the end part of the upper half section of the butt joint end 4 is in butt joint with a transmission port at the bottom of the servo motor 2, four groups of infusion ports 13 are horizontally distributed at the end part of the lower half section of the butt joint end 4, liquid input by the four groups of infusion ports 13 extends to the inner wall of the drainage sleeve 5, and the inner wall of the drainage sleeve 5 is corrugated. Wherein, the staff inserts the flow guide column and the packed column of the experiment to be prepared into the temperature control separation cylinder 7 along the upper ring buckle 12 and the lower ring buckle 8 in turn. After the insertion process is finished, the end part of the upper half section of the butt joint end 4 is in butt joint with a transmission port at the bottom of the servo motor 2, and rotary driving butt joint is finished. And the infusion port 13 for inputting acid-base solution is positioned at the end part of the lower half section of the butt joint end 4. In the process of infusion, the infusion drainage process is completed by utilizing the drainage sleeve 5 with the corrugated inner wall. The process can avoid the situation that the transfusion fluid can not uniformly flow to the filling column without being influenced by external force in the transfusion process.

As shown in fig. 1 and fig. 2, the bottom tube wall of the drainage sleeve 5 is a smooth barreled structure, the bottom tube wall of the drainage sleeve 5 is in clearance fit with the outer wall of the packed column, and the friction ring sleeve 18 extended integrally from the bottom tube wall of the drainage sleeve 5 is in friction contact with the inner wall of the detection cylinder 1. Wherein the friction collar 18 may enhance the mounting stability of the guide post. The clearance fit between the outer wall of the packed column and the smooth pipe wall at the bottom of the drainage sleeve 5 can further enhance the connection stability of the whole equipment.

As shown in fig. 1, 2 and 3, the packed column includes a packing sleeve 9, an experiment inner cylinder 15, a packing block 14 and inner ribs 16, the experiment inner cylinder 15 is in a two-group semi-arc cylinder wall structure, the two groups of experiment inner cylinders 15 are installed inside the packing sleeve 9 in a closed butt joint state, a plurality of groups of inner ribs 16 are uniformly distributed on the inner wall of the experiment inner cylinder 15, and the extension end parts of the inner ribs 16 are in limit contact with the packing block 14 filled inside the experiment inner cylinder 15; the pneumatic component butt joint device is characterized in that a butt joint bottom shaft 10 is installed at the bottom of the filling sleeve 9, the top of the butt joint bottom shaft 10 is of a plane supporting platform structure, a platform at the top of the butt joint bottom shaft 10 and the filling sleeve 9 are of a sealed butt joint structure, the bottom of the butt joint bottom shaft 10 is of a hemispherical cambered surface structure, and the end head of the bottom of the butt joint bottom shaft 10 and a butt joint disc 29 on the pneumatic component are of a push support structure. Wherein, the inside filling process is accomplished to the experiment inner tube 15 that the packed column utilized two sets of concatenations, and experiment inner tube 15 is removable subassembly, and at the in-process that needs to be changed inside packing piece and carry out follow-up experiment, can directly take out the concatenation combination of experiment inner tube 15, guarantees the inside experiment environment of packing sleeve 9. In order to further enhance the filling compactness of the filling block inside the experiment inner cylinder 15, a plurality of groups of inner ribs 16 are uniformly distributed on the inner wall of the experiment inner cylinder 15, and the inner ribs 16 can limit the moving range of the filling block by increasing the friction force between the inner ribs and the filling block. Just like the structure of the root for fixing soil. The butt joint bottom shaft 10 with the hemispherical cambered surface structure is in push butt joint contact with a butt joint port at the top of the butt joint disc 29.

As shown in fig. 1, 3 and 5, a concrete member segment is selectively inserted into the filling block 14 inside the filling sleeve 9, the concrete member segment is cylindrical, a binding groove formed in the top of the concrete member segment is welded to an integrally extended end at the bottom of the sealing cover 3, an outer ring of the sealing cover 3 and a ring rib 19 form a clamping structure, and the ring rib 19 is integrally connected to the upper half end of the inner wall of the butt-joint end 4. In order to limit the deep sliding of the concrete member segment, a binding groove formed in the top of the concrete member segment is welded with an integrally extended end at the bottom of the sealing cover 3, and the outer ring of the ring rib 19 is clamped with the outer ring of the sealing cover 3.

As shown in fig. 1 and 7, the pneumatic assembly includes a cylinder 27, a movable tank 28, and an air pump 24; the air cylinder 27 is in air supply butt joint with the air pump 24 through a pipeline, the air cylinder 27 is in a uniformly-divergent state along the center ring 25, water is flatly laid on the upper section of the base plate 26, the driving end of the air cylinder 27 extends out along the guide of the movable groove 28 and is synchronously connected with the butt joint disc 29, and the assembling port of the butt joint disc 29 faces upwards and is in a pushing support structure with the butt joint bottom shaft 10.

It should be noted that the above-mentioned contents only illustrate the technical idea of the present invention, and the protection scope of the present invention is not limited thereby, and it will be apparent to those skilled in the art that several modifications and embellishments can be made without departing from the principle of the present invention, and these modifications and embellishments fall within the protection scope of the claims of the present invention.

Claims (7)

1. A concrete member corrosion detection device comprises a servo motor (2), a cylinder (27) and a chassis (26); the method is characterized in that: air pump (24) are vertically installed in center ring (25) at chassis (26) up end center, the air feed port of air pump (24) bottom stretches out and docks along center ring (25) and with pneumatic component's cylinder (27) air feed, vertical telescopic link (23) of installing of air pump (24) top platform, ring frame (21) are installed to telescopic link (23) top sleeve axle (20) outer lane, six groups of extending arm (22) are equipped with to the frame in the clearance of ring frame (21) inner circle face, servo motor (2) are installed through the shackle in extending arm (22) terminal pilot hole (17), the transmission port of servo motor (2) bottom docks with the butt joint end (4) of the top of detecting section of thick bamboo (1) top half section transmission on, butt joint bottom shaft (10) and the pneumatic component of detecting section of thick bamboo (1) bottom butt joint dish (29).

2. The concrete member corrosion detecting apparatus according to claim 1, wherein: the detection barrel (1) comprises a temperature control separation barrel (7), a hollow shell is integrally packaged on the outer wall of the temperature control separation barrel (7), a cavity is reserved between the outer wall of the temperature control separation barrel (7) and the hollow shell, and a valve port installed in the middle section of the hollow shell is in selective air supply butt joint with an external pipeline.

3. The concrete member corrosion detection device of claim 2, wherein: an upper buckle (12) and a lower buckle (8) are respectively arranged at the upper end and the lower end of the temperature control partition cylinder (7), the caliber of the lower buckle (8) is smaller than that of the upper buckle (12), and a flow guide column and a filling column are respectively inserted into the upper buckle (12) and the lower buckle (8) along the inlet; the flow guide column comprises a butt joint end (4) and a drainage sleeve (5), the end of the upper half section of the butt joint end (4) is in butt joint with a transmission port at the bottom of the servo motor (2), four groups of infusion ports (13) are horizontally distributed at the end of the lower half section of the butt joint end (4), liquid input by the four groups of infusion ports (13) extends to the inner wall of the drainage sleeve (5), and the inner wall of the drainage sleeve (5) is corrugated.

4. The concrete member corrosion detection device of claim 3, wherein: the bottom pipe wall of the drainage sleeve (5) is of a smooth barreled structure, the bottom pipe wall of the drainage sleeve (5) is in clearance fit with the outer wall of the filling column, and the bottom pipe wall of the drainage sleeve (5) is extended integrally to form a friction ring sleeve (18) which is in friction contact with the inner wall of the detection cylinder (1).

5. The concrete member corrosion detection device of claim 4, wherein: the packing column comprises a packing sleeve (9), an experiment inner cylinder (15), packing blocks (14) and inner ribs (16), wherein the experiment inner cylinder (15) is of a two-group semi-arc-shaped cylinder wall structure, the two groups of experiment inner cylinders (15) are installed inside the packing sleeve (9) in a closed butt joint state, a plurality of groups of inner ribs (16) are uniformly distributed on the inner wall of the experiment inner cylinder (15), and extension end parts of the inner ribs (16) are in limit contact with the packing blocks (14) filled inside the experiment inner cylinder (15);

fill sleeve (9) bottom and install butt joint bottom shaft (10), butt joint bottom shaft (10) top becomes plane saddle structure, butt joint bottom shaft (10) top platform is sealed butt joint structure with filling sleeve (9), butt joint bottom shaft (10) bottom becomes hemisphere cambered surface structure, butt joint bottom shaft (10) bottom end is ejection bearing structure with butt joint dish (29) on the pneumatic component.

6. The concrete member corrosion detecting apparatus according to claim 5, wherein: concrete component sections are selectively inserted into the filling blocks (14) inside the filling sleeve (9), the concrete component sections are cylindrical, binding grooves formed in the tops of the concrete component sections are welded with integrally extended ends at the bottoms of the sealing covers (3), outer rings of the sealing covers (3) and ring ribs (19) are of clamping structures, and the ring ribs (19) are integrally connected to the upper half end portions of the inner walls of the butt joint ends (4).

7. The concrete member corrosion detecting apparatus according to claim 6, wherein: the pneumatic assembly comprises a cylinder (27), a movable groove (28) and an air pump (24); the air cylinder (27) is in butt joint with an air pump (24) through a pipeline for air supply, the air cylinder (27) is uniformly dispersed and water is tiled on the upper section of the chassis (26) along the center ring (25), the driving end of the air cylinder (27) extends out along the guide of the movable groove (28) and is synchronously connected with the butt joint disc (29), and the assembling port of the butt joint disc (29) faces upwards and is a pushing support structure with the butt joint bottom shaft (10).

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