CN211917217U

CN211917217U - Distributing device and forming system

Info

Publication number: CN211917217U
Application number: CN201922109189.9U
Authority: CN
Inventors: 张剑; 黄超; 谢忠全; 刘桥求
Original assignee: Hunan Yuanda Residential Intelligent Equipment Co ltd
Current assignee: Hunan Yuanda Residential Intelligent Equipment Co ltd
Priority date: 2019-11-29
Filing date: 2019-11-29
Publication date: 2020-11-13
Anticipated expiration: 2029-11-29

Abstract

The utility model relates to a distributing device, including delivery pump, inlet pipe, cloth passageway, feed back pipe and first flowmeter and second flowmeter. The delivery pump is used for being communicated with the stirrer; the feeding pipe is provided with a first feeding end and a first discharging end, and the first feeding end is communicated with a material conveying opening of the conveying pump; the material distribution channel is provided with a second feeding end, a second discharging end and a plurality of discharging ends arranged between the second feeding end and the second discharging end, the second feeding end is communicated with the first discharging end, and the plurality of discharging ends are used for being communicated with the forming mold; the material return pipe is provided with a third feeding end and a third discharging end, the third feeding end is communicated with the second discharging end, and the third discharging end is used for being communicated with the stirring machine; the first flow meter is arranged on the feeding pipe and used for measuring the amount of concrete flowing through the feeding pipe; the second flowmeter is arranged on the feed back pipe and used for measuring the amount of concrete flowing through the feed back pipe. The concrete is directly conveyed to the forming die, and the material can be distributed efficiently. The utility model discloses still relate to a molding system.

Description

Distributing device and forming system

Technical Field

The utility model relates to a precast concrete component production facility technical field especially relates to a distributing device and molding system.

Background

The concrete precast elements are usually precast and formed in a mold on a factory production line. At present, the material distribution mode of prefabricated parts on a production line is as follows: the mixing plant stirs the concrete, unloads the stirred concrete to the transport dolly, then carries the hopper of cloth machine with the concrete by the transport dolly in, realizes the cloth through the valve of the last different positions feed opening of control cloth machine at last. The concrete distribution process needs to be transferred for many times, and the defect of low efficiency exists.

SUMMERY OF THE UTILITY MODEL

In view of the above, it is necessary to provide a distributing device and a forming system capable of efficiently distributing a material on a precast concrete production line, in order to solve the problem of low efficiency of a material distribution method on the existing precast concrete production line.

A dispensing device, comprising:

the conveying pump is used for being communicated with the stirrer;

the feeding pipe is provided with a first feeding end and a first discharging end, and the first feeding end is communicated with a material conveying opening of the conveying pump;

the material distribution channel is provided with a second feeding end, a second discharging end and a plurality of discharging ends arranged between the second feeding end and the second discharging end, the second feeding end is communicated with the first discharging end, and the plurality of discharging ends are used for being communicated with a forming die;

the material return pipe is provided with a third feeding end and a third discharging end, the third feeding end is communicated with the second discharging end, and the third discharging end is used for being communicated with the stirring machine;

the first flow meter is arranged on the feeding pipe and used for measuring the amount of concrete flowing through the feeding pipe; and

and the second flowmeter is arranged on the feed back pipe and is used for measuring the amount of concrete flowing through the feed back pipe.

Through setting up foretell distribution system, the concrete that the agitator was stirred passes through the delivery pump sending to the inlet pipe, then gets into the distribution passageway, discharges to forming die in a plurality of discharge ends via the distribution passageway. Compared with the traditional mode of transporting concrete through a transport vehicle, the transporting mode reduces the transporting process, directly transports the concrete to a forming mold, and can efficiently distribute the concrete to form the prefabricated part.

In addition, the material return pipe is connected between the stirring machine and the material distribution channel, so that the concrete conveyed through the material inlet pipe can be determined, one part of the concrete enters the forming die, and the other part of the concrete returns to the stirring machine through the material return pipe, so that resources are saved, meanwhile, the material return pipe is matched with the first flow meter and the second flow meter, the amount of the concrete entering the forming die can be determined by calculating the difference value between the first flow meter and the second flow meter, and the production data statistics is facilitated.

In one embodiment, the material distribution device further includes a support assembly, the support assembly includes a bracket and a plurality of support members, the bracket is disposed at one side of the forming mold, and the support members are connected between the bracket and the material distribution channel.

In one embodiment, the material distribution channel comprises a connecting pipe, a frame-shaped pipe and a plurality of blanking pipes, wherein one end of the connecting pipe is communicated with the first discharging end, and the other end of the connecting pipe is communicated with the frame-shaped pipe;

the frame-shaped pipe is communicated with the material return pipe and is positioned above the forming die, and one side of the frame-shaped pipe, facing the forming die, is provided with a plurality of feed openings;

the plurality of blanking pipes are fixedly connected to the frame-shaped pipe, one end of each blanking pipe is communicated with one corresponding blanking opening, and the other end of each blanking pipe is communicated with the forming die.

In one embodiment, the distributing channel further includes a plurality of distributing hoppers, each distributing hopper corresponds to one of the discharging pipes, one end of each distributing hopper corresponds to the corresponding discharging port of the corresponding discharging pipe, and the other end of each distributing hopper is communicated with the forming mold.

In one embodiment, the distribution channel further includes a plurality of control valves, and each control valve is disposed on the corresponding discharge pipe and is configured to control an amount of the concrete passing through the discharge pipe.

In one embodiment, the material distribution device further comprises a controller, and the controller is electrically connected with the delivery pump and the control valves respectively.

In one embodiment, the controller is further electrically connected to the first flow meter and the second flow meter;

the distributing device further comprises a display, and the display is electrically connected with the controller.

In one embodiment, a side of the frame-shaped pipe facing away from the forming mold is provided with a feeding hole and a discharging hole, the connecting pipe is communicated with the feeding hole, and the third feeding end is communicated with the discharging hole.

In one embodiment, the frame-shaped pipe comprises a first short pipe, a first long pipe, a second short pipe and a second long pipe which are fixedly connected and communicated end to end in sequence;

the feed port is arranged on one side of the first short pipe, which is far away from the forming die, and the discharge port is arranged on one side of the second short pipe, which is far away from the forming die;

the blanking openings are even and divided into two groups, and the two groups of blanking openings are respectively arranged at intervals on one side of the first long pipe or one side of the second long pipe facing the forming die.

The utility model provides a molding system, includes mixer, forming die and as above the distributing device, the delivery pump is used for the intercommunication the mixer with the inlet pipe, a plurality of cloth passageway the discharge end with forming die intercommunication.

Drawings

Fig. 1 is a schematic structural diagram of a molding system according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of a blender and a dispensing device of the molding system shown in FIG. 1.

Detailed Description

In order to facilitate understanding of the present invention, the present invention will be described more fully hereinafter with reference to the accompanying drawings. Preferred embodiments of the present invention are shown in the drawings. The invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "or/and" includes any and all combinations of one or more of the associated listed items.

As shown in fig. 1 and 2, a material distribution system 100 according to an embodiment of the present invention includes a stirrer 10, a material distribution device, and a forming mold 30. The distributing device comprises a delivery pump 21, a feeding pipe 22, a distributing channel 23, a material return pipe 24, a first flowmeter 25 and a second flowmeter 26.

The delivery pump 21 is used for communicating with the blender 10, and the feeding pipe 22 has a first feeding end and a first discharging end, and the first feeding end is communicated with the material delivery port of the delivery pump 21.

The distribution channel 23 has a second feed end and a second discharge end, and a plurality of discharge ends arranged between the second feed end and the second discharge end, the second feed end being communicated with the first discharge end, the plurality of discharge ends being used for being communicated with the forming mold 30.

The material return pipe 24 has a third feeding end and a third discharging end, the third feeding end is communicated with the second discharging end, and the third discharging end is used for being communicated with the stirring machine 10.

A first flow meter 25 is provided to the feed pipe 22 for measuring the amount of concrete flowing through the feed pipe 22; a second flow meter 26 is provided in the return pipe 24 for measuring the amount of concrete flowing through the return pipe 24.

By providing the above-described distribution system, the mixed concrete in the mixer 10 is pumped by the delivery pump 21 to the feed pipe 22, then into the distribution channel 23, and discharged into the forming mold 30 via the plurality of discharge ends of the distribution channel 23. Compared with the traditional mode of transporting concrete by a transfer trolley, the transporting mode reduces the transporting process, directly transports the concrete to the forming mould 30, and can efficiently distribute the material to form the prefabricated part.

In addition, the material return pipe 24 is connected between the stirring machine 10 and the material distribution channel 23, so that it can be determined that one part of the concrete delivered through the material inlet pipe 22 enters the forming die 30, and the other part of the concrete returns to the stirring machine 10 through the material return pipe 24, resources are saved, and meanwhile, the material return pipe 24 is matched with the first flow meter 25 and the second flow meter 26, and the difference value between the first flow meter 25 and the second flow meter 26 can be calculated to determine the amount of the concrete entering the forming die 30, so that the statistical production data can be conveniently calculated.

It will be appreciated that the blender 10 generally has a blending cavity and a feeding port and a discharge port communicating with the cavity, the delivery pump 21 communicates with the discharge port of the blender 10, and the third discharge end of the return pipe 24 is disposed corresponding to the feeding port of the blender 10.

In some embodiments, the material distribution system includes a foundation 40, and the blender 10 and the forming die 30 are disposed on the foundation 40. Further, the distributing device further includes a supporting component 27, the supporting component 27 includes a bracket 272 and a plurality of supporting members 274, the bracket 272 is disposed at one side of the forming mold 30 and is supported on the foundation 40, and the supporting members 274 are connected between the bracket 272 and the distributing channel 23 for supporting the distributing channel 23 above the forming mold 30.

It should be noted that, in the conventional way of distributing concrete by using a transfer trolley, a bracket 272 may be provided around the mold, and the bracket 272 is used for supporting the distributing machine above the mold. Therefore, when the cloth channel 23 is disposed in the above embodiment, the original support 272 can be retained and directly connected between the cloth channel 23 and the support 272 via the support 274, so as to save the disposing time.

In some embodiments, the material distribution channel 23 includes a connecting pipe 232 and a frame pipe 234, one end of the connecting pipe 232 is connected to the first discharging end, the other end is connected to the frame pipe 234, the frame pipe 234 is connected to the material return pipe 24, the frame pipe 234 is located above the forming mold 30, and a plurality of discharging openings are opened on one side of the frame pipe 234 facing the forming mold 30.

The shape of the frame pipe 234 is determined according to the shape of the molding die 30, and the frame pipe is illustrated as a rectangular frame structure because the horizontal cross section of the corresponding molding die 30 is rectangular, but when the horizontal cross section of the corresponding molding die 30 is circular or other shapes, the corresponding frame pipe 234 may be a circular or other shape frame structure.

Meanwhile, the frame-shaped pipe 234 corresponds to the forming die 30 and is located above the forming die 30, so the frame-shaped pipe 234 needs to be supported by the support 274 and the bracket 272, and the connecting pipe 232 and the material return pipe 24 need to extend from the foundation 40 to be connected with the frame-shaped pipe 234, and thus need to be supported by the support 274 and the bracket 272.

In addition, the connection pipe 232 is a structure in the distribution passage 23 and is spaced apart from the feeding pipe 22 by the first flow meter 25 in the above embodiment, but in other embodiments, the connection pipe 232 and the feeding pipe 22 may be the same pipe, that is, the feeding pipe 22 is directly connected to the frame pipe 234. Similarly, the feed back pipe 24 may be composed of two pipes, and the second flowmeter 26 is spaced between the two pipes.

Further, the material distribution channel 23 further includes a plurality of material discharge pipes 236, the plurality of material discharge pipes 236 are all fixedly connected to the frame-shaped pipe 234, and one end of each material discharge pipe 236 is communicated with a corresponding material discharge opening, and the other end is used for being communicated with the forming mold 30. Thus, the design of the plurality of discharging pipes 236 is to ensure that the concrete poured in the forming mold 30 is distributed more uniformly, and the distributing efficiency is higher compared with the traditional distributing mode through the movable distributing machine.

Specifically, the frame-shaped pipe 234 includes a first short pipe, a first long pipe, a second short pipe and a second long pipe which are sequentially and fixedly connected and communicated end to end, the number of the feed openings is even, and the feed openings are divided into two groups, and the two groups of the feed openings are respectively arranged at intervals on one side of the first long pipe or the second long pipe facing the forming mold 30.

The even number of blanking pipes 236 are correspondingly arranged at the even number of blanking ports, and meanwhile, the size of the frame-shaped pipe 234 can be set to be matched with the forming mold 30, so that the blanking pipes 236 can be directly arranged in the vertical direction, the discharging speed is ensured, and meanwhile, the condition that concrete is easy to remain in the blanking pipes 236 due to the fact that the blanking pipes 236 are obliquely arranged is avoided.

In addition, the arrangement of the feeding ports also enables a plurality of feeding ports to be uniformly arranged corresponding to the forming mold 30, and the same is true for the feeding pipe 236, so that the concrete can be uniformly poured in the forming mold 30 in the above embodiment. Of course, in order to further ensure uniformity, the two short pipes may be provided with feed openings, and the specific opening manner may be determined according to actual conditions, but is mainly designed for the purpose of convenient pouring and uniform pouring.

In other embodiments, the number of the feeding ports may be odd, and the odd number of the feeding pipes 36 is set corresponding to the odd number of the feeding ports, as long as the concrete can be uniformly poured in the forming mold 30.

In some embodiments, the distribution channel 23 further comprises a plurality of control valves 235, each control valve 235 being disposed on a corresponding discharge pipe 236 for controlling the amount of concrete passing through the discharge pipe 236. Meanwhile, the control valve 235 can control the opening degree to adjust the blanking speed.

In addition, in combination with the above embodiment, the short pipe may be provided with a material outlet and a corresponding material outlet pipe 236, and then the corresponding valve may be opened when necessary, or closed when not necessary.

Further, the material distribution device further comprises a controller, and the controller is electrically connected with the delivery pump 21 and the plurality of control valves 235 respectively. The controller directly controls the control valves 235, manual operation of the control valves 235 is not needed, automatic control is achieved, and operation efficiency is improved.

In practical application, the material distribution device further comprises a display, the controller is also electrically connected with the first flow meter 25, the second flow meter 26 and the display at the same time, and the controller can transmit data of the first flow meter 25 and the second flow meter 26 to the display for displaying.

It is contemplated that the controller may be manually operated to effect control of the control valve 235 and the delivery pump 21. Further, the above-described embodiment explains that calculating the difference between the first flowmeter 25 and the second flowmeter 26 can determine the amount of concrete entering the molding die 30, and the difference can be directly calculated by the controller and displayed on the display, and the display can be in the form of data and/or a line graph specifically.

Thus, the operator can confirm the amount of concrete poured into the forming mold 30 by observing the data displayed on the display, thereby facilitating the operation. Of course, it is also possible to predetermine the amount of concrete required by the forming mold 30 to form a prefabricated member, and then input the value into the controller as a threshold value, and when the difference between the first flow meter 25 and the second flow meter 26 calculated by the controller reaches the threshold value, the controller controls the delivery pump 21 to stop and controls all the control valves 235 to be closed.

Based on the above structure, it should be noted that, for the difference between the first flowmeter 25 and the second flowmeter 26 and the amount of concrete poured into the forming mold 30: before casting, all the control valves 235 are closed, then the delivery pump 21 is turned on, the delivery pump 21 delivers the concrete along the feeding pipe 22, the connecting pipe 232, the frame-shaped pipe 234 and the return pipe 24, and the concrete also enters the discharging pipe 236 when passing through the frame-shaped pipe 234, but the discharging pipe 236 cannot enter the forming mold 30 because of the closed control valves 235.

The first flow meter 25 is still active when passing through the feed pipe 22, and the second flow meter 26 is not yet active, and the second flow meter 26 is active when the concrete is returned to the mixer 10 through the return pipe 24, indicating that the entire feed pipe 22, connecting pipe 232, frame pipe 234, feed pipe 236, and return pipe 24 are full of concrete. At this point the controller controls all of the control valves 235 to open and at the same time the controller begins to calculate the difference between the first flow meter 25 and the second flow meter 26.

Since the concrete is initially filled in the conduit and the concrete that subsequently flows into the conduit has only two directions, one is returned to mixer 10 and the other is transferred to form 30, the amount of concrete returned to mixer 10 is measured by second flow meter 26 and the concrete that subsequently flows into the conduit is the concrete entering from feed pipe 22 and is measured by first flow meter 25. So that the measurement of the first flow meter 25 minus the measurement of the second flow meter 26 is the amount of concrete delivered into the forming mould 30.

Of course, the concrete is fed from the feeding pipe 236, and a little residue is inevitably generated, but the above embodiment greatly reduces the amount of the residual concrete by vertically arranging the feeding pipe 236, and the amount of the residual concrete is negligible compared with the amount of the concrete for forming the prefabricated parts.

In some embodiments, the side of the frame pipe 234 facing away from the forming die 30 is provided with a feeding port and a discharging port, the connecting pipe 232 is communicated with the feeding port, and the third feeding port is communicated with the discharging port. Specifically, the feed inlet is provided on one side of the first short pipe departing from the forming mold 30, and the discharge outlet is provided on one side of the second short pipe departing from the forming mold 30.

Thus, the material inlet and outlet are disposed opposite to the material outlet, so as to avoid affecting the connection between the frame-shaped pipe 234 and the material outlet 236 when the frame-shaped pipe 234 is connected to the connecting pipe 232 and the material return pipe 24. Meanwhile, the arrangement can also show the connection and installation mode more clearly, thereby being convenient for installation.

In some embodiments, the material distribution channel 23 further includes a plurality of material distribution hoppers 238, each material distribution hopper 238 is disposed corresponding to a blanking pipe 236, one end of each material distribution hopper 238 corresponds to a blanking port of the corresponding blanking pipe 236, and the other end of each material distribution hopper 238 is communicated with the forming mold 30.

It should be noted that, for different forming molds 30, the sizes of the openings to be poured are different, the maximum pouring rate is different when pouring is performed on the corresponding forming mold 30, the blanking pipe 236 is directly connected to the frame pipe 234, and in order to ensure the pouring rate, the pipe diameter of the blanking pipe 236 needs to meet the maximum pouring rate.

However, when the opening facing the casting is smaller, a distribution hopper 238 is needed, the distribution hopper 238 is similar to a conventional hopper, two ends of the distribution hopper 238 are provided with openings communicated with each other, the opening at one end has a larger aperture than the opening at the other end, the opening with a larger aperture corresponds to the discharging pipe 236, and the opening with a smaller aperture corresponds to the opening cast by the forming mold 30. During pouring, the opening degree is controlled by the control valve 235 to adjust the pouring rate, and the concrete discharged from the discharging pipe 236 can be completely received by the distributing hopper 238 and input into the forming mold 30.

Meanwhile, it can be understood that the form of the distributing hopper 238 may be various, and the opening with larger caliber may not be changed, because the opening corresponds to the same unchanged blanking pipe 236; while the opening with smaller caliber needs to be designed corresponding to different forming dies 30.

In addition, the distribution hopper 238 needs to be fixed to the forming mold 30 during casting, and the fixing mode may be directly connected between the forming mold 30 and the distribution hopper 238 through some connecting members, or other modes may be adopted as long as relative fixing can be realized and the fixing mode corresponds to the discharge pipe 236 and the opening for casting.

Compared with the prior art, the utility model provides a distributing device and forming system have following advantage at least:

1) the concrete is directly conveyed into the forming die without a transfer trolley for transfer, so that the efficiency is improved;

2) the efficiency is further improved by the automatic control of the controller matched with the delivery pump and the control valves;

3) the difference value between the first flowmeter and the second flowmeter is the amount of concrete input into the forming die, so that data statistics is facilitated, and support is provided for automatic control;

4) a plurality of feed openings evenly distributed, the regulation of cooperation control valve opening simultaneously can guarantee pouring of concrete more even.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims

1. A material distribution device is characterized by comprising:

the conveying pump is used for being communicated with the stirrer;

2. The material distribution device according to claim 1, further comprising a support assembly, wherein the support assembly comprises a support and a plurality of support members, the support is disposed at one side of the forming mold, and the support members are connected between the support and the material distribution channel.

3. The material distribution device according to claim 1, wherein the material distribution channel comprises a connecting pipe, a frame-shaped pipe and a plurality of blanking pipes, one end of the connecting pipe is communicated with the first discharging end, and the other end of the connecting pipe is communicated with the frame-shaped pipe;

4. The distributing device according to claim 3, wherein the distributing passage further comprises a plurality of distributing hoppers, each distributing hopper corresponds to one of the blanking pipes, one end of each distributing hopper corresponds to a corresponding blanking port of the corresponding blanking pipe, and the other end of each distributing hopper is communicated with the forming mold.

5. The distribution device of claim 3, wherein the distribution channel further comprises a plurality of control valves, each control valve being disposed on a corresponding one of the down tubes for controlling the amount of concrete passing through the down tube.

6. The material distribution device according to claim 5, further comprising a controller electrically connected to the delivery pump and the plurality of control valves, respectively.

7. The cloth device of claim 6, wherein the controller is further electrically connected to the first flow meter and the second flow meter;

8. The material distribution device according to claim 3, wherein a feed inlet and a discharge outlet are formed in one side of the frame-shaped pipe, which is away from the forming die, the connecting pipe is communicated with the feed inlet, and the third feed end is communicated with the discharge outlet.

9. The material distribution device according to claim 8, wherein the frame-shaped pipe comprises a first short pipe, a first long pipe, a second short pipe and a second long pipe which are fixedly connected and communicated end to end;

the blanking openings are even and are two groups, and the two groups of blanking openings are respectively arranged at intervals on one side of the first long pipe or one side of the second long pipe facing the forming die.

10. A molding system comprising a mixer, a molding die and a dispensing device as claimed in any one of claims 1 to 9, said delivery pump being adapted to communicate said mixer with said feed tube, a plurality of said discharge ends of said dispensing channel being in communication with said molding die.