CN113310854B

CN113310854B - Shaking device for measuring sand content of slurry

Info

Publication number: CN113310854B
Application number: CN202110437492.0A
Authority: CN
Inventors: 夏伟才; 杨帆; 周剑雄; 黄国庆; 孙宁; 刘昌伟; 汪文煜; 方益飞
Original assignee: Hangzhou Asia Pacific Construction Supervision Consulting Co ltd
Current assignee: Hangzhou Asia Pacific Construction Supervision Consulting Co ltd
Priority date: 2021-04-22
Filing date: 2021-04-22
Publication date: 2022-08-30
Anticipated expiration: 2041-04-22
Also published as: CN113310854A

Abstract

The application relates to the technical field of slurry detection, in particular to a shaking device for measuring the sand content of slurry, which comprises a bracket, wherein the bracket is connected with a slide bar in a sliding manner along the vertical direction, the slide bar is provided with a measuring tube and a driving mechanism for driving the measuring tube to rotate on a vertical surface, and the measuring tube is provided with a stirring plate and a tube plug for sealing the tube opening of the measuring tube; the support is provided with a pushing mechanism, the pushing mechanism comprises a motor arranged on the support, and an output shaft of the motor is provided with a push plate which rotates on the vertical surface and is used for pushing the poking plate to rise. This application can improve the separation efficiency of grit.

Description

Shaking device for measuring sand content of slurry

Technical Field

The application relates to the technical field of mud detects, especially relates to a mud sand content volume is measured and is used shake device.

Background

In the construction industry, it is often necessary to measure the sand content of the slurry. The sand content of the slurry refers to the volume percentage of solid-phase particles which can not pass through a 203-mesh sieve hole or have the particle diameter of more than 0.074 mm in the slurry.

At present, in the process of measuring the sand content of slurry, workers are required to add the slurry and clean water into a measuring pipe, and then sand is separated from the slurry in a hand-cranking mode. The inventors believe that this separation is inefficient and therefore require improvement.

Disclosure of Invention

In order to improve the separation efficiency of grit, this application provides a mud contains sand volume and measures with shaking device.

The application provides a pair of mud sand content volume is measured with shaking device adopts following technical scheme: a shaking device for measuring the sand content of slurry comprises a bracket, wherein the bracket is connected with a slide bar in a sliding way along the vertical direction, the slide bar is provided with a measuring tube and a driving mechanism for driving the measuring tube to rotate on the vertical surface, and the measuring tube is provided with a stirring plate and a tube plug for sealing the orifice of the measuring tube; the support is provided with a pushing mechanism, the pushing mechanism comprises a motor arranged on the support, and an output shaft of the motor is provided with a push plate which rotates on the vertical surface and is used for pushing the poking plate to rise.

By adopting the technical scheme, in the separation process of the sand, the measuring tube is driven to rotate by the driving mechanism, so that the tube opening of the measuring tube is upward, then the slurry and the clean water are added into the measuring tube, and the tube opening of the measuring tube is blocked by the tube plug; then the motor drives the push plate to rotate, and the push plate pushes the poking plate to rise in the rotating process; when the push plate is separated from the stirring plate, the measuring pipe descends due to the gravity of the push plate, and the push plate is in clearance type abutting against the stirring plate, so that the continuous shaking of the measuring pipe is realized, and the separation efficiency of sand is improved. After the sand separation is finished, the measuring pipe is driven to rotate through the driving mechanism, so that the pipe opening of the measuring pipe faces downwards, and then the pipe plug is taken down, so that the liquid in the measuring pipe can be poured out.

Optionally, two first sliding rails extending in the vertical direction are arranged on the support, and two ends of each sliding bar are respectively embedded in the corresponding first sliding rails in a sliding manner.

By adopting the technical scheme, the stability of the sliding rod in the sliding process is improved.

Optionally, the end of the sliding rod is rotatably embedded in the first sliding rail; the driving mechanism comprises a gear fixedly sleeved on the sliding rod and a rack meshed with the gear, and the rack extends in the vertical direction and is arranged on the bracket.

Through adopting above-mentioned technical scheme, at the lift in-process of slide bar, the gear will mesh in the rack for slide bar, gear and survey buret are rotatory, so that the workman adds mud and clear water in the survey pipe, and made things convenient for the workman to pour the liquid in the survey pipe.

Optionally, the gear is provided with a positioning rod, the bracket is provided with a second slide rail for the positioning rod to be slidably embedded, and the second slide rail is located above the rack; when the gear rises and is separated from the rack, the positioning rod is embedded into the second sliding rail in a sliding mode, and the poking plate is located on the rotating track of the push plate.

Through adopting above-mentioned technical scheme, break away from behind the rack when the gear rises, the locating lever will slide and imbed in the second slide rail, survey buret this moment and will only follow vertical direction motion for when the push pedal is promoting to dial the board and rise, survey the difficult emergence of buret and rock, thereby improved the stability of surveying buret at the shake in-process.

Optionally, a third slide rail for slidably embedding the positioning rod is arranged on the bracket, and the third slide rail is positioned below the rack; when the gear falls and is separated from the rack, the positioning rod is embedded into the third sliding rail in a sliding mode.

Through adopting above-mentioned technical scheme, fall and break away from behind the rack when the gear, the locating lever will slide and imbed in the third slide rail, survey buret this moment and will only follow vertical direction motion, when the workman will survey intraductal liquid and pour out, survey the difficult emergence of buret and rock to the stability of surveying buret when pouring liquid has been improved.

Optionally, a supporting seat for supporting the sliding rod is arranged on the first sliding rail; when the positioning rod slides into the third slide rail, the slide rod is placed on the supporting seat.

Through adopting above-mentioned technical scheme, when the locating rod slided into the third slide rail, the slide bar will be shelved on the supporting seat, and slide bar, gear and survey buret will unable continuation decline this moment, survey the buret and keep stable because of self gravity, have guaranteed the stability of surveying the buret when pouring liquid.

Optionally, an elastic protrusion for supporting the sliding rod is arranged on the inner wall of the first sliding rail; when the gear rises to be separated from the rack, the sliding rod is placed on the elastic bulge, and the poking plate is positioned on the rotating track of the pushing plate.

By adopting the technical scheme, after the gear rises and is separated from the rack, the sliding rod is placed on the elastic bulge, and the sliding rod, the gear and the measuring tube are kept stable at the moment; the poking plate is positioned on the rotating track of the push plate, and when the motor drives the push plate to rotate, the push plate can cause the measuring tube to shake continuously; after the sand is separated, the motor is closed, and the measuring pipe descends to the elastic bulge due to the self gravity; because of the slide bar, the gear and the measuring pipe have certain potential energy in the descending process, the slide bar extrudes and deforms the elastic bulge, the slide bar moves to the lower part of the elastic bulge, the gear is meshed with the gear, the measuring pipe is turned over on a vertical surface, and the pipe opening of the measuring pipe faces downwards, so that liquid in the measuring pipe can be poured out.

Optionally, the sidewall of the plug is threaded to engage the inner wall of the measurement tube.

Through adopting above-mentioned technical scheme, improved the stability of stopcock and to surveying the sealed effect of buret.

To sum up, the application comprises the following beneficial technical effects:

1. the sliding rod, the driving mechanism, the poking plate and the pushing mechanism are arranged, and the push plate is in clearance type contact with the poking plate, so that continuous shaking of the measuring pipe is realized, and the separation efficiency of sand is improved;

2. the arrangement of the gear and the rack ensures that the measuring pipe can be turned over in the descending process so as to pour out the liquid in the measuring pipe;

3. the arrangement of the positioning rod, the second slide rail and the third slide rail improves the stability of the measuring pipe in the shaking and pouring processes;

4. elastic bulge's setting, the gear rises and breaks away from behind the rack, and the slide bar will shelve on elastic bulge, survey buret this moment will remain stable, shake when surveying buret and accomplish the back, and the slide bar will be elastic bulge extrusion deformation and move to elastic bulge's below, and the gear will mesh in the gear for survey buret upset on vertical face, the mouth of pipe of surveying buret will be down, so that the pouring of measuring intraductal liquid.

Drawings

FIG. 1 is a schematic diagram of the overall structure in the embodiment of the present application;

FIG. 2 is a schematic structural diagram of a pushing mechanism and a driving mechanism in an embodiment of the present application;

fig. 3 is a schematic view showing a structure when the measuring pipe pours liquid in the embodiment of the present application.

Reference numerals: 1. a support; 11. a first slide rail; 111. an elastic bulge; 12. a second slide rail; 13. a third slide rail; 14. a supporting seat; 2. a slide bar; 3. a measurement tube; 31. a pipe plug; 32. a poking plate; 4. a pushing mechanism; 41. a motor; 42. pushing the plate; 5. a drive mechanism; 51. a gear; 52. a rack; 53. and (5) positioning the rod.

Detailed Description

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

The embodiment of the application discloses a shake device is used in measurement of mud sand content. As shown in figure 1, a mud contains sand volume and measures with shake device, including support 1, be fixed with two first slide rails 11 that extend along vertical direction on the support 1, two slide rails 11 slide-in are equipped with the slide bar 2 that is the level setting with the root, are fixed with on the slide bar 2 and survey buret 3, and the mouth of pipe internal thread that surveys buret 3 cooperates in stopcock 31. During the sand separation, the opening of the measuring tube 3 is first turned upwards, slurry and clean water are introduced into the measuring tube 3, and the opening of the measuring tube 3 is then blocked by the plug 31.

As shown in fig. 1 and 2, a horizontally disposed poking plate 32 is fixed on the outer wall of the measuring pipe 3; the pushing mechanism 4 is arranged on the support 1, the pushing mechanism 4 comprises a motor 41 fixed on the support 1, an output shaft of the motor 41 extends along the axial direction of the sliding rod 2 and is fixed with two pushing plates 42 which are arranged circumferentially; an elastic protrusion 111 is fixed on the inner wall of the first slide rail 11.

When the slide bar 2 rests on the elastic projection 111, the toggle plate 32 will be located on the rotation trajectory of the push plate 42; when the motor 41 drives the push plates 42 to rotate, one of the push plates 42 will rotate to push the toggle plate 32 to rise; when the push plate 42 is separated from the poking plate 32, the measuring pipe 3 will descend due to the self gravity, and then the other push plate 42 will continue to push the poking plate 32 to ascend; starting through the motor 41, the shaking of the measuring pipe 3 can be realized, and the separation efficiency of the sand is improved.

The end part of the sliding rod 2 is rotatably embedded in the first sliding rail 11; a driving mechanism 5 is arranged on the sliding rod 2, the driving mechanism 5 comprises a gear 51 fixedly sleeved on the sliding rod 2, a rack 52 extending along the vertical direction is meshed on the gear 51, and the rack 52 is fixed on the bracket 1; a positioning rod 53 extending in the vertical direction is fixed to the gear 51; a second slide rail 12 extending in the vertical direction is fixed on the bracket 1, the second slide rail 12 is located above the rack 52, and the positioning rod 53 is embedded in the second slide rail 12 in a sliding manner. At the shake in-process of surveying buret 3, locating lever 53 will slide in second slide rail 12 for slide bar 2 is difficult at first slide rail 11 internal rotation, so survey buret 3 will only be liftable, has improved the stability of surveying buret 3 at the shake in-process.

After the sand is separated, the motor 41 is turned off, and the measuring tube 3 has a certain potential energy in the descending process, so that the measuring tube 3 drives the sliding rod 2 to press the elastic bulge 111 to be deformed, the sliding rod 2 moves to the position below the elastic bulge 111, and the gear 51 is meshed with the rack 52; during the lowering of the slide bar 2, the gear wheel 51 will rotate on the rack 52 and the measuring tube 3 will be turned over in the vertical plane.

As shown in fig. 2 and 3, the third slide rail 13 extends along the vertical direction on the bracket 1, the third slide rail 13 is located below the rack 52, and the positioning rod 53 is slidably embedded in the third slide rail 13; a supporting seat 14 is fixed on the first slide rail 11, and the supporting seat 14 is located on the motion track of the slide bar 2. After the gear 51 is slid off the rack 52, the measuring pipe 3 has rotated 180 degrees, and the opening of the measuring pipe 3 faces downward; the positioning rod 53 slides into the third slide rail 13, so that the slide bar 2 is not easy to rotate, and the measuring tube 3 can only be lifted; after the slide bar 2 descends and rests on the supporting seat 14, the slide bar 2, the gear 51 and the measuring pipe 3 stop descending, and at the moment, the pipe plug 31 is taken down from the pipe orifice of the measuring pipe 3, so that the liquid in the measuring pipe 3 can be poured out, and the operation is convenient.

The embodiment of the application provides a mud sand content volume is measured with implementation principle of shake device does: during the separation of sand, the slide bar 2 will rest on the elastic projections 111 and the orifice of the measuring tube 3 will be facing upwards, whereupon slurry and clean water are introduced into the measuring tube 3 and the orifice of the measuring tube 3 is blocked by the plug 31.

Then the motor 41 will drive the push plate 42 to rotate, the push plate 42 will rotate to push the dial plate 32 to rise, and after the push plate 42 is separated from the dial plate 32, the measuring pipe 3 will fall due to its own gravity, thereby realizing the shaking of the measuring pipe 3 and improving the separation efficiency of sand. After the sand is separated, the motor 41 is closed, the measuring tube 3 drives the sliding rod 2 to press the elastic bulge 111 to be deformed, the sliding rod 2 moves to the position below the elastic bulge 111, and the gear 51 is meshed with the rack 52; during the lowering of the slide bar 2, the gear wheel 51 will rotate on the rack 52 and the measuring tube 3 will be turned over in the vertical plane.

After the gear 51 is slid off the rack 52, the measuring pipe 3 has rotated 180 degrees, and the opening of the measuring pipe 3 faces downward; when the sliding rod 2 descends and rests on the supporting seat 14, the sliding rod 2, the gear 51 and the measuring tube 3 stop descending, and at the moment, the pipe plug 31 is taken down from the pipe orifice of the measuring tube 3, so that the liquid in the measuring tube 3 can be poured out, and the operation is convenient.

The above are preferred embodiments of the present application, and the scope of protection of the present application is not limited thereto, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims

1. The utility model provides a mud sand content volume is measured with shaking device which characterized in that: the device comprises a support (1), wherein the support (1) is connected with a slide rod (2) in a sliding manner along the vertical direction, the slide rod (2) is provided with a measuring tube (3) and a driving mechanism (5) for driving the measuring tube (3) to rotate on the vertical surface, and the measuring tube (3) is provided with a stirring plate (32) and a tube plug (31) for sealing the tube opening of the measuring tube (3); the pushing mechanism (4) is arranged on the support (1), the pushing mechanism (4) comprises a motor (41) arranged on the support (1), and a pushing plate (42) which rotates on a vertical surface and is used for pushing the poking plate (32) to ascend is arranged on an output shaft of the motor (41); the support (1) is provided with two first sliding rails (11) extending in the vertical direction, and two ends of the sliding rod (2) are respectively embedded in the corresponding first sliding rails (11) in a sliding manner; the end part of the sliding rod (2) is rotatably embedded in the first sliding rail (11); the driving mechanism (5) comprises a gear (51) fixedly sleeved on the sliding rod (2) and a rack (52) meshed with the gear (51), and the rack (52) extends in the vertical direction and is arranged on the bracket (1); a positioning rod (53) is arranged on the gear (51), a second sliding rail (12) for the sliding embedding of the positioning rod (53) is arranged on the bracket (1), and the second sliding rail (12) is positioned above the rack (52); when the gear (51) rises and is separated from the rack (52), the positioning rod (53) is embedded into the second sliding rail (12) in a sliding manner, and the poking plate (32) is positioned on the rotating track of the pushing plate (42); a third sliding rail (13) for the positioning rod (53) to be embedded in a sliding manner is arranged on the bracket (1), and the third sliding rail (13) is positioned below the rack (52); when the gear (51) descends and is separated from the rack (52), the positioning rod (53) is embedded into the third sliding rail (13) in a sliding manner; a supporting seat (14) for supporting the sliding rod (2) is arranged on the first sliding rail (11); when the positioning rod (53) slides into the third slide rail (13), the slide rod (2) will rest on the support seat (14).

2. The shake-up device for measuring the sand content of the slurry according to claim 1, wherein: an elastic bulge (111) for supporting the sliding rod (2) is arranged on the inner wall of the first sliding rail (11); when the gear (51) rises to be separated from the rack (52), the sliding rod (2) is placed on the elastic bulge (111), and the poking plate (32) is positioned on the rotating track of the pushing plate (42).

3. The shake-up device for measuring the sand content of the slurry as claimed in claim 1, wherein: the side wall of the pipe plug (31) is in threaded fit with the inner wall of the measuring pipe (3).