CN219455630U - Tap device for hydraulic engineering cement strength detection - Google Patents

Abstract

The utility model relates to a technical field that cement detected especially relates to a hydraulic engineering cement intensity detects uses compaction device, and it includes base, vibration mechanism, compaction platform, mould, presses frame and slide mechanism, the compaction platform passes through vibration mechanism to be set up on the base, the mould is placed on the compaction platform, press the frame to pass through slide mechanism slides and sets up on the compaction platform and be used for fixing the mould, be provided with positioning mechanism on the compaction platform, positioning mechanism includes the locating piece, the locating piece sets up on the compaction platform and be provided with two, two the locating piece is used for the location the mould just is located respectively the both sides of mould. The application has the effect of improving the working efficiency.

Description

Tap device for hydraulic engineering cement strength detection

Technical Field

The application relates to the technical field of cement detection, in particular to a compaction device for hydraulic engineering cement strength detection.

Background

At present, along with the development of the hydraulic engineering industry, the demand for concrete is larger and larger, and the strength of the concrete has a great relation to the safety of building construction, so that the detection of the strength of the concrete is crucial, and the tapping machine is equipment which is used for detecting the strength of the hydraulic engineering cement and is suitable for a concrete strength detection sample support.

Among the prior art, the plain bumper includes body, shaking table and presses frame and mould, and the shaking table setting is on the body, and the mould is placed on the shaking table, presses the frame to rotate on the shaking table and is used for compressing tightly the mould on the shaking table.

In the process of realizing the application, the inventor finds that at least the following problems exist in the technology, when vibration is performed, firstly, an empty die is placed on a compaction table, then, a press frame is rotated to fix the die on the compaction table, the compaction table is lack of positioning, alignment between the die and the press frame is inconvenient, time adjustment is needed, and further, the working efficiency is reduced.

Disclosure of Invention

In order to improve work efficiency, this application provides a hydraulic engineering cement intensity detects and uses compaction device.

The utility model provides a pair of hydraulic engineering cement intensity detects uses compaction device adopts following technical scheme:

the utility model provides a hydraulic engineering cement intensity detects and uses tap device, includes base, vibration mechanism, tap platform, mould, presses frame and slide mechanism, the tap platform passes through vibration mechanism to be set up on the base, the mould is placed tap bench, press the frame through slide mechanism slides and sets up tap bench and be used for fixing the mould, tap bench is provided with positioning mechanism, positioning mechanism includes the locating piece, the locating piece sets up tap bench just is provided with two, two the locating piece is used for the location the mould just is located respectively the both sides of mould.

By adopting the technical scheme, when hydraulic engineering construction is carried out, the cement strength is generally required to be detected, the mould is firstly placed on the compaction table, the mould is respectively abutted against the two positioning blocks, then the pressing frame is driven by the sliding mechanism to approach the mould, the mould is slightly adjusted, the pressing frame is tightly pressed on the mould, cement, water and sand are added into the construction, the cement colloid after the construction is mixed, the mixed cement colloid is added into the mould, the vibration mechanism is started, the compaction table is driven by the vibration mechanism to vibrate for sixty times, then the cement colloid is added into the mould, the vibration mechanism is started to vibrate for sixty times again, then the mould is detached, the cement colloid protruding out of the surface of the mould is scraped, the surface is leveled, then the mould and the cement colloid are placed in a curing chamber for curing, after the curing time is up, the mould is removed, and the cement strength is detected; the positioning mechanism is convenient for positioning the die and the pressing frame, reduces the time for adjusting the position waste of the die, and further improves the working efficiency.

Optionally, the press frame slides along vertical direction through the sliding mechanism and sets up on the plain bumper, positioning mechanism still includes the locating plate, the locating plate sets up press frame is last and with the lateral wall butt of mould.

Through adopting above-mentioned technical scheme, place the mould behind the compaction bench, with the drive of sliding mechanism press the frame towards the mould be close to, the locating plate butt with the lateral wall of mould can reduce the dislocation of pressing frame and mould, and then the filling of the cement colloid of being convenient for work efficiency further improves.

Optionally, the positioning plates are four, and the four positioning plates are disposed around the outer peripheral wall of the mold.

Through adopting above-mentioned technical scheme, place the mould behind the plain bumper, be close to towards the mould with the drive press frame of sliding mechanism, four locating plates are with the surrounding of mould for mould and the complete dislocation of press frame further reduce, and then make the filling of cement colloid more convenient, make work efficiency further improve.

Optionally, the side walls of the positioning plates, which are close to each other, are provided with guide surfaces.

Through adopting above-mentioned technical scheme, the guide surface of setting is convenient for mould slide in between the locating plate, and then presses the location of frame and mould more convenient and fast, and then makes work efficiency further improve.

Optionally, the sliding mechanism includes dead lever, mount and locking subassembly, be provided with four on the plain bumper the dead lever, four on the dead lever common slip one the mount, press the frame with the mount is connected, locking subassembly sets up on the dead lever and is used for fixing the mount.

Through adopting above-mentioned technical scheme, place the mould behind two locating pieces, the slip mount, the frame is driven to press the frame towards the mould to be close to, presses frame and mould butt, then with locking assembly with the mount locking, the sliding mechanism simple structure of setting, the operation of being convenient for, and then make work efficiency further improve.

Optionally, the pressing frame is slidingly connected to the fixing frame, a vibration mechanism is arranged on the fixing frame, the vibration mechanism comprises a sliding rod, a reset spring and a reciprocating assembly, the sliding rods are arranged at two ends of the pressing frame, and the sliding rods are slidingly arranged on the fixing frame; the sliding rods are sleeved with the reset springs, and two ends of each reset spring are respectively connected with the fixing frame and the pressing frame; the reciprocating assembly is arranged on the fixing frame and connected with the pressing frame and drives the pressing frame to slide.

By adopting the technical scheme, after the die is pressed on the compaction table, the reciprocating assembly drives the fixing frame to slide, the fixing frame drives the dynamic frame and the die to slide, and the reset spring stretches to drive the die to shake; the setting shakes the flat mechanism for cement colloid in the mould is more level and smooth, and then when having reduced cement colloid and filled, the flattening of cement colloid in the mould has reduced above-mentioned step, makes work efficiency further improve.

Optionally, the reciprocating assembly includes butt piece, cam and driving motor, driving motor sets up on the mount, the cam sets up on driving motor's the output shaft, the butt piece sets up press on the frame and with the cam butt.

By adopting the technical scheme, the driving motor is started, the driving motor drives the cam to rotate, the cam drives the abutting block to slide, the abutting block drives the fixing frame to slide, and the fixing frame drives the die to slide; the reciprocating assembly is simple in structure and convenient to operate.

Optionally, the compaction platform with rotate on the lateral wall of mould butt and be connected with the ball.

Through adopting above-mentioned technical scheme, when the mould slides, the ball that sets up can reduce frictional force, reduces driving motor's energy consumption, can reduce the wearing and tearing to the plain bumper simultaneously, prolongs the life of this equipment.

In summary, the present application includes the following beneficial technical effects:

1. when hydraulic engineering construction is carried out, the cement strength is generally required to be detected, firstly, a mould is placed on a compaction table, the mould is respectively abutted against two positioning blocks, then a sliding mechanism is used for driving a pressing frame to approach the mould, then the mould is slightly adjusted, the pressing frame is tightly pressed on the mould, cement, water and sand are added into construction, then the mixed cement colloid is added into the mould, a vibration mechanism is started, the vibration mechanism drives the compaction table to vibrate for sixty times, then the cement colloid is added into the mould, then the vibration mechanism is started to vibrate for sixty times again, then the mould is detached, the cement colloid protruding out of the surface of the mould is scraped off, the surface is leveled, then the mould and the cement colloid are placed in a curing chamber for curing, after the curing time is up, the mould is removed, and the cement strength is detected; the positioning mechanism is convenient for positioning the die and the pressing frame, reduces the time wasted in adjusting the position of the die, and further improves the working efficiency;

2. after the die is pressed on the compaction table, the reciprocating assembly drives the fixing frame to slide, the fixing frame drives the pressing frame and the die to slide, and the reset spring stretches to drive the die to shake; the setting of the vibration leveling mechanism enables the cement colloid in the die to be more level, so that the leveling of the cement colloid in the die is reduced when the cement colloid is filled, the steps are reduced, and the working efficiency is further improved;

3. when the mould slides, the ball that sets up can reduce frictional force, reduces driving motor's energy consumption, can reduce the wearing and tearing to the plain bumper simultaneously, prolongs the life of this equipment.

Drawings

FIG. 1 is a schematic structural diagram of a tap device for detecting the strength of hydraulic engineering cement according to an embodiment of the present application;

FIG. 2 is a schematic structural diagram of a vibration leveling mechanism according to an embodiment of the present application;

fig. 3 is a schematic structural diagram of a positioning mechanism in an embodiment of the present application.

Reference numerals: 100. a base; 200. a vibration mechanism; 210. a first support; 220. a second support; 230. a rotating lever; 240. an impact block; 250. a power assembly; 251. a driving wheel; 252. a driving block; 253. a power motor; 300. a compaction table; 400. a mold; 500. pressing a frame; 600. a sliding mechanism; 610. a fixed rod; 620. a fixing frame; 630. a locking assembly; 631. a telescopic spring; 632. a locking nut; 633. a threaded rod; 700. a positioning mechanism; 710. a positioning block; 720. a positioning plate; 800. a vibrating mechanism; 810. a slide bar; 820. a reset spring; 830. a reciprocating assembly; 831. an abutment block; 832. a cam; 833. a driving motor; 840. and (3) rolling balls.

Detailed Description

The present application is described in further detail below in conjunction with figures 1-3.

The embodiment of the application discloses hydraulic engineering cement intensity detects and uses tap device.

Referring to fig. 1, the compaction device for hydraulic engineering cement strength detection comprises a base 100, a vibration mechanism 200 arranged on the base 100, a compaction table 300 arranged on the vibration mechanism 200, a die 400 arranged on the compaction table 300, a sliding mechanism 600 arranged on the compaction table 300, a pressing frame 500 arranged on the sliding mechanism 600 and used for fixing the die 400, and a positioning mechanism 700 arranged on the compaction table 300 and used for positioning the die 400.

Referring to fig. 1, the vibration mechanism 200 includes a first support 210, one end of the base 100 is integrally provided with the first support 210, the other end of the base 100 is integrally provided with a second support 220, and the first support 210 and the second support 220 are located at the same side; the first support 210 is rotatably connected with two rotating rods 230, one end, far away from the first support 210, of each rotating rod 230 is connected with a compaction table 300, each compaction table 300 is positioned above the corresponding second support 220, one side, close to the corresponding second support 220, of each compaction table 300 is fixedly connected with a collision block 240, and each collision block 240 can be abutted against the corresponding second support 220; the second support 220 is provided with a power assembly 250, the power assembly 250 comprises a power motor 253 fixedly connected to the second support 220, an output shaft of the power motor 253 is connected with a driving wheel 251, and the vertical section of the driving wheel 251 is shaped like a Chinese character 'pin'; the compaction table 300 is fixedly connected with a driving block 252, one side of the driving block 252, which is close to the driving wheel 251, is subjected to chamfering treatment, and the driving block 252 can be abutted against the peripheral side wall of the driving wheel 251; when the power motor 253 is started, the power motor 253 drives the driving wheel 251 to rotate, the driving wheel 251 drives the driving block 252 to ascend, and the driving block 252 is separated from the driving wheel 251 along with the rotation of the driving wheel 251, the compaction table 300 falls down on the second support 220 under the influence of gravity.

Referring to fig. 2 and 3, the sliding mechanism 600 includes four fixing rods 610 fixedly connected to the tapping table 300, a fixing frame 620 is slidably connected to the fixing rods 610, and a hole for placing the pressing frame 500 is formed in the middle of the fixing frame 620; the locking assembly 630 is arranged on the fixed rod 610, the locking assembly 630 comprises a threaded rod 633 integrally arranged at the end part of the fixed rod 610, a locking nut 632 is connected to the threaded rod 633 in a threaded manner, the locking nut 632 abuts against the side wall of the fixed frame 620, which is far away from the compaction table 300, the fixed rod 610 is sleeved with a telescopic spring 631, and two ends of the telescopic spring 631 are respectively connected with the compaction table 300 and the fixed frame 620; the telescopic spring 631 drives the fixing frame 620 to abut against the locking nut 632.

Referring to fig. 2 and 3, a vibration leveling mechanism 800 is disposed on a fixing frame 620, the vibration leveling mechanism 800 includes four sliding rods 810, two sliding rods 810 are fixedly connected to two ends of a pressing frame 500 respectively, the sliding rods 810 at two ends of the pressing frame 500 are slidably connected to the fixing frame 620, a limiting block is fixedly connected to one end of the sliding rod 810 away from the pressing frame 500, and the limiting block can be abutted to the side wall of the fixing frame 620; a reset spring 820 is sleeved on each sliding rod 810, and two ends of the reset spring 820 are respectively connected with the fixing frame 620 and the pressing frame 500; the fixed frame 620 is provided with a reciprocating assembly 830, the reciprocating assembly 830 comprises a driving motor 833 fixedly connected to the fixed frame 620, and the driving motor 833 is positioned at one end of the sliding rod 810 at one end far away from the sliding rod 810 at the other end; the output shaft of the driving motor 833 is connected with a cam 832, the side wall of the press frame 500 far away from the die 400 is fixedly connected with an abutting block 831, and the abutting block 831 can be abutted with the cam 832; the driving motor 833 is started, the driving motor 833 drives the abutting block 831 to slide, the abutting block 831 drives the pressing frame 500 to slide, the reset springs 820 at the two ends respectively extend or compress, and after the cam 832 is separated from the pressing frame 500, the pressing frame 500 is driven to slide in a reciprocating manner.

Referring to fig. 2 and 3, a plurality of balls 840 are rollingly coupled to a sidewall of the tapping table 300 adjacent to the mold 400, and the balls 840 abut against a bottom wall of the mold 400 and are rotated relatively.

Referring to fig. 2 and 3, the positioning mechanism 700 includes two positioning blocks 710 fixedly connected to the tapping table 300, and the two positioning blocks 710 are respectively located at two sides of the sliding direction of the mold 400; the side wall of the pressing frame 500, which is close to the die 400, is fixedly connected with four positioning plates 720, the four positioning plates 720 are connected end to end and are arranged around the outer side wall of the die 400, the four positioning plates 720 are respectively abutted with the four outer side walls of the die 400, and the side wall of the positioning plates 720, which is close to the compaction table 300, is provided with a guide surface, which is convenient for the alignment of the die 400 and the pressing frame 500.

The embodiment of the application adopts the implementation principle that the compaction device for hydraulic engineering cement strength detection is as follows: placing the die 400 on the compaction table 300, abutting the side wall of the die 400 with the positioning block 710, pressing the pressing frame 500 towards the die 400, abutting the die 400 with the guide surface of the positioning plate 720, driving the balls 840 to roll by the die 400, aligning the die 400 with the pressing frame 500, continuing to press the pressing frame 500, and rotating the locking nut 632 to abut against the fastening frame 620; then taking out a certain amount of cement, water and sand stone to stir and mix to form cement colloid, filling the cement colloid into the mold 400, and then starting a power motor 253, wherein the power motor 253 drives a driving wheel 251 to rotate, so that the compaction table 300 vibrates up and down; meanwhile, a driving motor 833 is started, the driving motor 833 drives a cam 832 to rotate, the cam 832 rotates and drives an abutting block 831 to slide, the abutting block 831 drives a pressing frame 500 to slide, the pressing frame 500 drives reset springs 820 at two ends to shrink or stretch, and after the cam 832 is separated from the abutting block 831, the pressing frame 500 slides reciprocally; after the compaction table 300 vibrates sixty times, cement colloid is continuously added into the mold 400, then the operation is continuously performed, maintenance is performed after vibration is completed, and then mold removal detection is performed.

The foregoing are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims (8)

1. The utility model provides a hydraulic engineering cement intensity detects and uses compaction device, includes base (100), vibration mechanism (200), compaction platform (300), mould (400), presses frame (500) and slide mechanism (600), compaction platform (300) are in through vibration mechanism (200) setting on base (100), mould (400) are placed on compaction platform (300), press frame (500) are passed through slide mechanism (600) slide and set up on compaction platform (300) and be used for fixing mould (400), a serial communication port, be provided with positioning mechanism (700) on compaction platform (300), positioning mechanism (700) include locating piece (710), locating piece (710) set up on compaction platform (300) and be provided with two, two locating piece (710) are used for the location mould (400) and are located respectively the both sides of mould (400).

2. The compaction device for hydraulic engineering cement strength detection according to claim 1, wherein the press frame (500) is slidably arranged on the compaction table (300) along a vertical direction through the sliding mechanism (600), the positioning mechanism (700) further comprises a positioning plate (720), and the positioning plate (720) is arranged on the press frame (500) and is abutted to an outer side wall of the die (400).

3. The tap device for hydraulic engineering cement strength detection according to claim 2, wherein four positioning plates (720) are provided, and four positioning plates (720) are provided around the outer circumferential wall of the die (400).

4. A tap device for hydraulic engineering cement strength detection according to claim 3, wherein the side walls of the positioning plate (720) close to each other are provided with guide surfaces.

5. The compaction device for hydraulic engineering cement strength detection according to claim 1, wherein the sliding mechanism (600) comprises a fixing rod (610), a fixing frame (620) and a locking assembly (630), four fixing rods (610) are arranged on the compaction table (300), one fixing frame (620) slides on the four fixing rods (610) together, the press frame (500) is connected with the fixing frame (620), and the locking assembly (630) is arranged on the fixing rods (610) and used for fixing the fixing frame (620).

6. The compaction device for hydraulic engineering cement strength detection according to claim 5, wherein the pressing frame (500) is slidingly connected to the fixing frame (620), a leveling mechanism (800) is arranged on the fixing frame (620), the leveling mechanism (800) comprises a sliding rod (810), a reset spring (820) and a reciprocating assembly (830), the sliding rod (810) is arranged at two ends of the pressing frame (500), and the sliding rod (810) is slidingly arranged on the fixing frame (620); the sliding rods (810) are respectively sleeved with the reset springs (820), and two ends of each reset spring (820) are respectively connected with the fixing frame (620) and the pressing frame (500); the reciprocating assembly (830) is arranged on the fixing frame (620), and the reciprocating assembly (830) is connected with the pressing frame (500) and drives the pressing frame (500) to slide.

7. The tap device for hydraulic engineering cement strength detection according to claim 6, wherein the reciprocating assembly (830) comprises an abutment block (831), a cam (832) and a driving motor (833), the driving motor (833) is arranged on the fixing frame (620), the cam (832) is arranged on an output shaft of the driving motor (833), and the abutment block (831) is arranged on the pressing frame (500) and is abutted against the cam (832).

8. The compaction device for hydraulic engineering cement strength detection according to claim 6, wherein balls (840) are rotatably connected to a side wall of the compaction table (300) abutting against the die (400).