CN220840926U - Intelligent concrete mixing plant - Google Patents

Abstract

The utility model discloses an intelligent concrete mixing plant, which has the technical scheme that a slump detection assembly is arranged, a part of concrete samples are placed in a Schrad cone, the Schrad cone rises and is separated from a concrete sample, at the moment, the concrete sample loses restriction and can have certain slump, then a laser range finder is used for measuring the slump height of the concrete sample, the slump can be calculated according to the slump height, the laser range finder transmits a ranging signal to a signal receiving terminal through a signal transmitting terminal, the slump of the concrete can be monitored remotely, and the intelligent concrete mixing plant is used for solving the problem that the concrete with more accurate slump is difficult to obtain due to the fact that the volume of the mixing plant is larger, the mixing time is longer, and the mixing plant in a comparison patent is difficult to detect the slump of the concrete with different mixing degrees in time; through setting up the slider, can drive the lift of slap awl, adjust the height of slap awl.

Description

Intelligent concrete mixing plant

Technical Field

The utility model relates to the field of concrete mixing stations, in particular to an intelligent concrete mixing station.

Background

A concrete mixing plant is an industrial apparatus for producing concrete, which is an important tool for mixing and stirring raw materials such as cement, sand, aggregate (such as stones and sand), water, additives and the like to prepare concrete;

Application number: in CN 202120562066.5's chinese patent, a cleaning system for a belt conveyer of a stirring station, a belt conveyer of a stirring station and a stirring station are disclosed, and the cleaning system for a belt conveyer of a stirring station can collect and weigh the residual water attached on a washing conveying belt, send the residual water into a stirring device of a stirring station, and recover the residual water, thereby not only reducing the consumption of water resources, but also eliminating the need for sewage treatment of the residual water generated by the washing of the part, and reducing the burden of environmental protection.

However, when the concrete is stirred, the volume of the stirring station is larger, the stirring time is longer, and the stirring station in the comparison patent is difficult to timely detect the slump of the concrete with different stirring degrees, so that the concrete with more accurate slump is difficult to obtain, and therefore, the intelligent concrete stirring station is provided.

Disclosure of utility model

In order to overcome the defects of the prior art, the utility model aims to provide an intelligent concrete mixing plant, a slump detection assembly is arranged, a part of concrete samples are placed in a Steper cone, the Steper cone rises to separate from the concrete samples, at the moment, the concrete samples lose restriction and can slump to a certain extent, then a laser range finder is used for measuring the slump height of the concrete samples, the slump can be calculated according to the slump, and the laser range finder transmits a ranging signal to a signal receiving terminal through a signal transmitting terminal, so that the slump of the concrete can be monitored remotely.

The technical aim of the utility model is realized by the following technical scheme:

The utility model provides an intelligent concrete mixing plant, includes the stirring station main part, the external connection of stirring station main part has supporting component, the right-hand member of stirring station main part is connected with sampling assembly, sampling assembly's below is provided with slump detection assembly.

The slump detection assembly comprises a Schrad cone, wherein a connecting ring is fixedly connected to the outer portion of the Schrad cone, a laser range finder is fixedly connected to the outer portion of the connecting ring, and a signal transmitting terminal is fixedly connected to the outer surface of the laser range finder.

Through setting up slump detection component, the concrete sample of partly is put into the slap awl in the timing, after the concrete sample is poured to certain altitude, let slap awl rise under the effect of lead screw, break away from the concrete sample, the concrete sample loses the restriction and can take place certain slump this moment, then move slap awl horizontal migration away from the concrete sample for laser range finder is located the top of the highest department of concrete sample, let slap awl decline to bottom and ground laminating reuse laser range finder measure the slump height of concrete sample, can calculate the slump according to this altitude, laser range finder 403 is through signal transmission terminal 404 with range finding signal transmission for signal receiving terminal, the slump of remote monitoring concrete.

Further, the other end fixedly connected with connecting rod of go-between, the right side of slap awl is provided with the base, the inside fixedly connected with servo motor one of base, the upper end fixedly connected with transmission shaft of servo motor one output, the upper end fixedly connected with elevating socket of transmission shaft, elevating socket rotates with the base to be connected.

Through setting up the elevating socket, servo motor one drives the transmission shaft and rotates to drive the elevating socket and rotate, and then can adjust the angle of laser range finder.

Further, a sliding groove is formed in the left end of the lifting seat, a second servo motor is fixedly connected to the inside of the lifting seat, and a screw rod is fixedly connected to the upper end of the output end of the second servo motor.

By arranging the screw rod, the second servo motor can drive the screw rod to rotate.

Further, the outer end of the screw rod is movably connected with a sliding block, and the sliding block is matched with the screw rod.

Through setting up the slider, the rotation of lead screw can drive the slider up-and-down motion to can drive the lift of slap awl, adjust the height of slap awl.

Further, a guide rod is fixedly connected to the inside of the lifting seat, and the guide rod penetrates through the sliding block and is in sliding connection with the sliding block.

Further, the slider is fixedly connected with the connecting rod, and the connecting rod penetrates through the sliding groove and is in sliding connection with the sliding groove.

Further, the sampling assembly comprises a sampling hose which is fixedly communicated with the right end of the stirring station main body, and the outer end of the sampling hose is fixedly connected with a sampling electromagnetic valve.

Further, the supporting component comprises a support, the support is fixedly connected to the lower end of the stirring station main body, and the left end of the stirring station main body is fixedly connected with a climbing ladder.

In summary, the utility model has the following beneficial effects:

1. The slump detection assembly is arranged, a part of concrete samples are placed in the Schrad cone, the Schrad cone rises to separate from the concrete sample, at the moment, the concrete sample loses restriction and can generate certain slump, then the laser range finder is used for measuring the slump height of the concrete sample, the slump can be calculated according to the slump height, the laser range finder transmits a ranging signal to the signal receiving terminal through the signal transmitting terminal, and the slump of the concrete can be monitored remotely;

2. Through setting up the slider, the rotation of lead screw can drive the slider up-and-down motion to can drive the lift of slap awl, adjust the height of slap awl.

Drawings

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

Fig. 2 is a schematic view showing a structure of a slump detecting assembly in a three-dimensional manner in the present embodiment;

FIG. 3 is a schematic view of the structure of a Sipulan cone in the present embodiment;

fig. 4 is a schematic view of a three-dimensional structure of the lifting seat in the present embodiment;

fig. 5 is a schematic view of a three-dimensional structure of a screw in this embodiment.

In the figure, 1, a stirring station main body; 2. a support assembly; 201. a bracket; 202. climbing ladder; 3. a sampling assembly; 301. a sampling hose; 302. a sampling electromagnetic valve; 4. a slump detection assembly; 401. a slap cone; 402. a connecting ring; 403. a laser range finder; 404. a signal transmitting terminal; 405. a connecting rod; 406. a base; 407. a servo motor I; 408. a transmission shaft; 409. a lifting seat; 410. a chute; 411. a servo motor II; 412. a screw rod; 413. a slide block; 414. a guide rod.

Detailed Description

The present utility model will be described in further detail with reference to the accompanying drawings.

Wherein like parts are designated by like reference numerals. It should be noted that the words "front", "back", "left", "right", "upper" and "lower" used in the following description refer to directions in the drawings, and the words "bottom" and "top", "inner" and "outer" refer to directions toward or away from, respectively, the geometric center of a particular component.

Referring to fig. 1, an intelligent concrete mixing plant according to a preferred embodiment of the present utility model includes a mixing plant main body 1, a support assembly 2 is connected to the outside of the mixing plant main body 1, a sampling assembly 3 is connected to the right end of the mixing plant main body 1, and a slump detection assembly 4 is disposed below the sampling assembly 3.

Referring to fig. 1-3, the slump detection assembly 4 comprises a slap cone 401, wherein a connecting ring 402 is fixedly connected to the outer part of the slap cone 401, a laser range finder 403 is fixedly connected to the outer part of the connecting ring 402, and a signal transmitting terminal 404 is fixedly connected to the outer surface of the laser range finder 403.

Through setting up slump detection component 4, the concrete sample of partly is put into the slap awl 401 at regular time, after the concrete sample is poured to certain altitude, let slap awl 401 rise under the effect of lead screw 412, break away from the concrete sample, the concrete sample loses the restriction and can take place certain slump this moment, then keep away from the concrete sample with slap awl 401 horizontal migration again, make laser range finder 403 be located the top of concrete sample highest department, let slap awl 401 descend to the bottom and ground laminating and reuse laser range finder 403 measure the slump height of concrete sample, can calculate the slump according to this altitude, laser range finder 403 passes through signal transmission terminal 404 with the range finding signal transmission for signal receiving terminal, can the slump of remote monitoring concrete.

Referring to fig. 1-4, the other end of the connecting ring 402 is fixedly connected with a connecting rod 405, the right side of the slap cone 401 is provided with a base 406, the interior of the base 406 is fixedly connected with a first servo motor 407, the upper end of the output end of the first servo motor 407 is fixedly connected with a transmission shaft 408, the upper end of the transmission shaft 408 is fixedly connected with a lifting seat 409, and the lifting seat 409 is rotatably connected with the base 406.

By arranging the lifting seat 409, the first servo motor 407 drives the transmission shaft 408 to rotate, so that the lifting seat 409 is driven to rotate, and the angle of the laser range finder 403 can be adjusted.

Referring to fig. 1, 4 and 5, a sliding groove 410 is formed in the left end of the lifting seat 409, a second servo motor 411 is fixedly connected to the inside of the lifting seat 409, and a screw rod 412 is fixedly connected to the upper end of the output end of the second servo motor 411.

By arranging the screw rod 412, the second servo motor 411 can drive the screw rod 412 to rotate.

Referring to fig. 1 and 5, a slider 413 is movably connected to the outer end of the screw 412, and the slider 413 is adapted to the screw 412.

Through setting up slider 413, the rotation of lead screw 412 can drive slider 413 up-and-down motion to can drive the lift of slap cone 401, adjust the height of slap cone 401.

Referring to fig. 1 and 5, a guide rod 414 is fixedly connected to the inside of the lifting seat 409, and the guide rod 414 penetrates the slider 413 and is slidably connected to the slider 413.

Referring to fig. 1 and 5, the slider 413 is fixedly connected to the connection rod 405, and the connection rod 405 penetrates the chute 410 and is slidably connected to the chute 410.

By providing the guide rod 414, the slider 413 can be guided to prevent deflection.

Referring to fig. 1, the sampling assembly 3 includes a sampling hose 301, the sampling hose 301 is fixedly connected to the right end of the stirring station body 1, and a sampling solenoid valve 302 is fixedly connected to the outer end of the sampling hose 301.

By arranging the sampling hose 301, the sampling electromagnetic valve 302 is opened and closed at regular time by a PLC programmable controller of the mixing station, and then concrete samples can be added into the inside of the Sirader cone 401 through the hose.

Referring to fig. 1, the support assembly 2 includes a bracket 201, the bracket 201 is fixedly connected to the lower end of the stirring station main body 1, and the left end of the stirring station main body 1 is fixedly connected to a climbing ladder 202.

By providing the bracket 201 and the climbing ladder 202, it is possible to facilitate climbing to the height of the stirring station main body 1 for operation.

The specific implementation process comprises the following steps: firstly, the sampling electromagnetic valve 302 is opened and closed at regular time by a PLC programmable controller of the mixing station, so that concrete samples can be added into the interior of the Sirap cone 401 through a hose, and a part of concrete samples are put into the interior of the Sirap cone 401 at regular time.

After the concrete sample is poured to a certain height, the second servo motor 411 can drive the screw rod 412 to rotate, and the rotation of the screw rod 412 can drive the sliding block 413 to move upwards, so that the slap cone 401 can be driven to move upwards, the concrete sample is separated from the concrete sample, and at the moment, the concrete sample is out of limit and can slump to a certain extent.

Finally, the slap cone 401 is horizontally moved away from the concrete sample, the laser range finder 403 is positioned above the highest position of the concrete sample, the slap cone 401 is lowered to the bottom to be attached to the ground, the laser range finder 403 is used for measuring the slump height of the concrete sample, the slump can be calculated according to the slump height, the laser range finder 403 transmits a ranging signal to the signal receiving terminal through the signal transmitting terminal 404, and the slump of the concrete can be monitored remotely.

The foregoing has shown and described the basic principles and main features of the present utility model and the advantages of the present utility model. It will be understood by those skilled in the art that the present utility model is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present utility model, and various changes and modifications may be made without departing from the spirit and scope of the utility model, which is defined in the appended claims. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (8)

1. An intelligent concrete mixing plant, its characterized in that: including stirring station main part (1), the external connection of stirring station main part (1) has supporting component (2), the right-hand member of stirring station main part (1) is connected with sampling component (3), the below of sampling component (3) is provided with slump detection component (4), slump detection component (4) are including slap awl (401), the outside fixedly connected with go-between (402) of slap awl (401), the outside fixedly connected with laser range finder (403) of go-between (402), the surface fixedly connected with signal transmission terminal (404) of laser range finder (403).

2. An intelligent concrete mixing plant according to claim 1, characterized in that: the utility model discloses a stopper, including base (409) and base (406), go-between (402) other end fixedly connected with connecting rod (405), the right side of slap awl (401) is provided with base (406), the inside fixedly connected with servo motor (407) of base (406), the upper end fixedly connected with transmission shaft (408) of servo motor (407) output, the upper end fixedly connected with elevating seat (409) of transmission shaft (408), elevating seat (409) and base (406) rotate and are connected.

3. An intelligent concrete mixing plant according to claim 2, characterized in that: the left end of lifting seat (409) has seted up spout (410), the inside fixedly connected with servo motor two (411) of lifting seat (409), servo motor two (411) output's upper end fixedly connected with lead screw (412).

4. An intelligent concrete mixing plant according to claim 3, characterized in that: the outer end of the screw rod (412) is movably connected with a sliding block (413), and the sliding block (413) is matched with the screw rod (412).

5. An intelligent concrete mixing plant according to claim 4, wherein: the inside fixedly connected with guide bar (414) of elevating seat (409), guide bar (414) run through slider (413) and with slider (413) sliding connection.

6. An intelligent concrete mixing plant according to claim 5, wherein: the sliding block (413) is fixedly connected with the connecting rod (405), and the connecting rod (405) penetrates through the sliding groove (410) and is in sliding connection with the sliding groove (410).

7. An intelligent concrete mixing plant according to claim 1, characterized in that: the sampling assembly (3) comprises a sampling hose (301), the sampling hose (301) is fixedly communicated with the right end of the stirring station main body (1), and the outer end of the sampling hose (301) is fixedly connected with a sampling electromagnetic valve (302).

8. An intelligent concrete mixing plant according to claim 1, characterized in that: the support assembly (2) comprises a support (201), the support (201) is fixedly connected to the lower end of the stirring station main body (1), and the left end of the stirring station main body (1) is fixedly connected with a climbing ladder (202).