CN219445605U - Material conveying, weighing and stirring system applicable to GRC and UHPC simultaneously - Google Patents

Abstract

The utility model discloses a material conveying, weighing and stirring system applicable to GRC and UHPC simultaneously, which comprises a feeding component, a material conveying tank and a material stirring tank, wherein the feeding component comprises a material conveying tank, a material stirring tank and a material stirring tank; the storage assembly comprises a cement storage tank and a sand storage tank, and the sand storage tank is connected with the feeding tank through a feeding pipe; the predicting assembly comprises a predicting tank, wherein the cement storage tank and the sand storage tank are respectively connected with the predicting tank through a conveyor, and a manual feed inlet is further formed in the predicting tank; the material distributing assembly comprises a Y-shaped discharging frame connected to the lower end of the expected tank, wherein a material distributing block is arranged in the Y-shaped discharging frame, and one outlet of the lower end of the Y-shaped discharging frame is selected by rotating the material distributing block; the stirring assembly comprises two stirring devices, and the upper ends of the two stirring devices are respectively connected with one outlet of the Y-shaped discharging frame. According to the utility model, the manual feed inlet is arranged in the anticipating tank, so that raw materials of UHPC can be manually added, and the method can be simultaneously suitable for production of GRC and UHPC.

Description

Material conveying, weighing and stirring system applicable to GRC and UHPC simultaneously

Technical Field

The utility model relates to the technical field of production equipment of GRC and UHPC, in particular to a material conveying, weighing and stirring system applicable to both GRC and UHPC.

Background

GRC (GlassfiberReinforcedConcrete) the Chinese name is glass fiber reinforced concrete, UHPC (Ultra-HighPerformance concrete) and the Chinese name is high strength reactive powder concrete. Wherein, the GRC is a composite material composed of cement, sand, water, glass fiber, admixture and other aggregates and mixtures. Cement and water are hardened after hydration reaction to form gel-set cement, sand (or other materials) is firmly cemented together, glass fiber is cemented and anchored, the material with good performance is formed, the sand plays roles of filling and skeleton in GRC, and the glass fiber plays a role of reinforcement; UHPC is a high-strength, high-toughness and low-porosity ultrahigh-strength cement-based material, and the basic configuration principle is as follows: by increasing fineness and activity of the structural components, coarse aggregate is not used, and pores and microcracks in the material are minimized, so that ultra-high strength and high durability are obtained.

These 2 materials are commonly used in commercial space applications where irregular wall or ceiling designs are seen. GRC and UHPC are two more emerging materials, but due to their powerful properties, they have been widely used today.

Because the material proportion of GRC is disclosed, when a user produces GRC, different raw materials can be respectively and independently filled into the storage tank, and then are respectively mixed and stirred according to a specific proportion to obtain the GRC material. The UHPC is a patent product of European company, only pre-synthesized bagged raw materials can be purchased at home at present, the bagged raw materials are mixed by a plurality of materials, and different materials are mixed according to a specific proportion, so that the raw materials of the UHPC cannot be prepared by users. In other words, raw materials of UHPC cannot be individually charged into the storage tanks, or otherwise, non-uniformity occurs in the material fed from the storage tanks, so that serious problems occur in the production quality of UHPC.

In summary, in the prior art, because of the difference of raw materials required for production, the production equipment of UHPC and the production equipment of GRC cannot be used commonly, but in one building project, two kinds of building materials are likely to be needed at the same time, if two sets of production equipment are provided, the occupied area of the two sets of production equipment is large, so that the space cost is higher, and the overall cost of the project is further obviously increased.

Disclosure of Invention

In order to overcome the technical defect that production equipment of GRC and UHPC materials cannot be commonly used, the utility model provides a material conveying, weighing and stirring system which is applicable to both GRC and UHPC materials.

In order to solve the problems, the utility model is realized according to the following technical scheme:

the utility model discloses a material conveying, weighing and stirring system applicable to GRC and UHPC simultaneously, which comprises the following components:

the feeding assembly comprises a feeding tank;

the storage assembly comprises a cement storage tank and a sand storage tank, and the sand storage tank is connected with the feeding tank through a feeding pipe;

the predicting assembly comprises a predicting tank, wherein the cement storage tank and the sand storage tank are respectively connected with the predicting tank through a conveyor, and a manual feed inlet is further formed in the predicting tank;

the material distributing assembly comprises a Y-shaped discharging frame connected to the lower end of the expected tank, wherein a material distributing block is arranged in the Y-shaped discharging frame, and one outlet at the lower end of the Y-shaped discharging frame is selected by rotating the material distributing block;

the stirring assembly comprises two stirring devices, and the upper ends of the two stirring devices are respectively connected with one outlet of the Y-shaped discharging frame.

As a preferred implementation of the utility model, the feeding assembly further comprises a feeding trolley and a feeding room, wherein the feeding trolley is used for transporting the sand vessels of the device to the feeding room;

the side of the feeding house is provided with an opening corresponding to the feeding travelling crane, and the lower end of the feeding house is communicated with the feeding tank.

As the preferable implementation of the utility model, the lower end of the feeding room is provided with a funnel-shaped feeding hole, a hinged feeding cover is arranged above the feeding hole, and a pneumatic valve is arranged between the feeding hole and the feeding tank.

As a preferred implementation of the present utility model, further comprising:

the working platform comprises a first layer of platform and a second layer of platform, and stairs are arranged between the first layer of platform and the second layer of platform.

As the preferable implementation of the utility model, the feeding room is arranged on a first-layer platform, the anticipation tank is arranged on a second-layer platform, the material distribution component is arranged between the first-layer platform and the second-layer platform, and the stirring device is arranged on the first-layer platform;

the two-layer platform is provided with a through hole matched with the pre-charging tank, and the one-layer platform is provided with a funnel-shaped discharge hole adjacent to the stirring device.

As a preferred implementation of the utility model, a weighing frame is arranged on the periphery of the anticipation tank in a surrounding manner, and the anticipation tank passes through the weighing frame;

the side of the expected tank is provided with a plurality of sliding grooves, the outer side of each sliding groove is respectively connected with a sliding block frame, the inner side of each sliding block frame is provided with a sliding block matched with the sliding groove, the lower end face of each sliding block frame is connected with the weighing frame, and the expected tank can slide up and down relative to the weighing frame through the movable connection of the sliding grooves and the sliding block frames;

the side of expecting the jar fixedly connected with strengthening rib, be equipped with weighing sensor between the lower terminal surface of strengthening rib and the weighing frame.

As a preferred implementation of the present utility model, the number of the cement storage tanks is 1, and the number of the sand storage tanks is 3;

cement storage tank with the maximum storage capacity of cement storage tank parallel arrangement, the maximum storage capacity of cement storage tank be 60 tons, the maximum storage capacity of sand storage tank be 30 tons.

As the preferable implementation of the utility model, dust collectors are respectively arranged at the upper ends of the cement storage tank, the sand storage tank and the pre-material tank.

As a preferred implementation of the utility model, the distributor block is driven by a cylinder arranged outside the Y-shaped discharging frame, the distributor block comprises two semicircular side surfaces and a rectangular bottom surface, and the distributor block can rotate around the arc top position of the semicircular side surfaces so as to adjust the inclination direction of the bottom surface of the distributor block.

As the preferable implementation of the utility model, the charging tank is a high-pressure pneumatic charging tank; the conveyor is a spiral conveyor; the stirring equipment is a vertical shaft planetary stirrer.

Compared with the prior art, the utility model has the beneficial effects that:

the utility model is provided with the anticipating component, the distributing component and the stirring component which are sequentially connected from top to bottom, so that materials can be selectively distributed into the stirring device after being anticipated and weighed, and accurate feeding control is realized. In GRC production, materials in a cement storage tank and a sand storage tank are respectively conveyed into a prediction tank in proportion, and are premixed and weighed, so that a feeding procedure of GRC production is realized. And two stirring devices are arranged in the stirring assembly, so that parallel independent processing of GRC materials and UHPC materials can be realized, or dry-wet separation stirring processing can be carried out.

Drawings

The utility model is described in further detail below with reference to the attached drawing figures, wherein:

FIG. 1 is a schematic perspective view of the present utility model;

FIG. 2 is a schematic illustration of the connection of the anticipation assembly, the distribution assembly, and the stirring assembly of the present utility model;

FIG. 3 is a schematic top view of the present utility model;

in the figure:

1. a feed assembly; 11. feeding a material tank; 12. feeding and driving; 13. a feeding room;

2. a storage assembly; 21. a cement storage tank; 22. a sand storage tank; 23. a conveyor;

3. a anticipation component; 31. a pre-charging tank; 311. a manual feed port; 32. a weighing rack;

4. a material distribution component; 41. A Y-shaped discharging frame;

5. a stirring assembly; 51. A stirring device;

6. and a working platform.

Detailed Description

The preferred embodiments of the present utility model will be described below with reference to the accompanying drawings, it being understood that the preferred embodiments described herein are for illustration and explanation of the present utility model only, and are not intended to limit the present utility model.

The detailed features and advantages of the present utility model will be set forth in the following detailed description of the embodiments, which is provided to enable any person skilled in the art to make and use the present utility model, and the related objects and advantages of the present utility model will be readily understood by those skilled in the art from the present disclosure, claims and drawings. The following examples are presented to illustrate the aspects of the utility model in further detail, but are not intended to limit the scope of the utility model in any way.

In addition, the following drawings disclose embodiments of the present utility model, for the purpose of making the drawings clean, some conventional structures and elements may be schematically depicted in the drawings, and some of the features in the drawings may be slightly enlarged or changed in scale or size to achieve the purpose of facilitating understanding and viewing of the technical features of the present utility model, but the present utility model is not limited thereto. Further, coordinate axes are provided in the drawings to facilitate understanding of the relative positional relationship and actuation direction of the elements.

It should be understood that the direction or positional relationship indicated by the terms "upper", "lower", etc. are based on the direction or positional relationship shown in the drawings, are merely for convenience in describing the present utility model and simplifying the description, and do not indicate or imply that the apparatus or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present utility model. Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the present utility model, unless otherwise indicated, the meaning of "a plurality" is two or more.

In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements.

In addition, the terms "end," "portion," "region," and "place" may be used hereinafter to describe particular elements and structures or particular features thereon or therebetween, but these elements and structures are not limited by these terms. "and/or" may also be used herein to refer to a combination comprising one or more of the listed elements or structures. Furthermore, the terms "substantially," "about," or "approximately" when used in connection with a range of sizes, concentrations, temperatures, or other physical or chemical properties or characteristics may be used hereinafter to cover deviations in the upper and/or lower limits of the ranges of properties or characteristics that may exist, or to represent acceptable deviations from manufacturing tolerances or analysis procedures, while still achieving the desired results.

Moreover, unless defined otherwise, all terms or words used herein, including technical and scientific terms and other words, are to be taken to include their ordinary meanings as understood by one of ordinary skill in the art. Furthermore, the definitions of the words and terms used in the present specification should be interpreted as including a meaning consistent with the technical field of the present utility model. These terms are not to be construed as being overly idealized or formal intent unless expressly so defined.

As shown in fig. 1 to 3, the utility model is a preferable structure of a material conveying and weighing and stirring system which is applicable to both GRC and UHPC.

The utility model discloses a material conveying, weighing and stirring system applicable to GRC and UHPC simultaneously, which comprises the following components:

a feed assembly 1 comprising a feed tank 11;

the storage component 2 comprises a cement storage tank 21 and a sand storage tank 22, wherein the sand storage tank 22 is connected with the feeding tank 11 through a feeding pipe;

the predicting assembly 3 comprises a predicting tank 31, wherein the cement storage tank 21 and the sand storage tank 22 are respectively connected with the predicting tank 31 through a conveyor 23, and a manual feed port 311 is further arranged on the predicting tank 31; a switch is arranged at the lower end of the pre-charging bucket 31, and the switch is turned on to feed the material into the material distribution assembly 4 after weighing reaches the standard;

a distributing assembly 4 comprising a Y-shaped discharging frame 41 connected to the lower end of the anticipatory jar 31, wherein the Y-shaped discharging frame 41 has a distributing block therein, and one of outlets of the lower end of the Y-shaped discharging frame 41 is selected by rotating the distributing block;

the stirring assembly 5 comprises two stirring devices 51, and the upper ends of the two stirring devices 51 are respectively connected with one outlet of the Y-shaped discharging frame 41. The two stirring devices 51 can respectively stir dry materials and wet materials to realize the stirring work of dry-wet separation, so that the application range of the utility model is obviously improved. Or, the two stirring devices 51 can also stir different materials respectively, and only the orientation of the distributor in the Y-shaped discharging frame 41 is required to be adjusted during feeding, so that one stirring device 51 can stir and produce GRC materials, and the other stirring device 51 can stir and produce UHPC materials which are manually added by a user.

As a preferred implementation of the present utility model, the feeding assembly 1 further comprises a feeding crane 12 and a feeding room 13, wherein the feeding crane 12 is used for transporting sand vessels of the device to the feeding room 13; the side of the feeding house 13 is provided with an opening corresponding to the feeding travelling crane 12, and the lower end of the feeding house 13 is communicated with the feeding tank 11. The lower extreme of material loading room 13 is provided with the feed inlet of funnel form, the top of feed inlet is equipped with articulated feeding lid, the feed inlet with be provided with pneumatic valve between the material loading jar 11.

Specifically, the method further comprises the following steps:

the working platform 6 comprises a first-layer platform and a second-layer platform, and a stair is arranged between the first-layer platform and the second-layer platform.

As a preferable implementation of the utility model, the feeding house 13 is arranged on a first-layer platform, the anticipation tank 31 is arranged on a second-layer platform, the material distribution assembly 4 is arranged between the first-layer platform and the second-layer platform, and the stirring device 51 is arranged on the first-layer platform;

the two layers of platforms are provided with through holes matched with the anticipating tank 31, and the one layer of platforms are provided with funnel-shaped discharge holes adjacent to the stirring device 51.

As a preferred implementation of the present utility model, the periphery of the anticipation tank 31 is provided with a weigh frame 32, and the anticipation tank 31 passes through the weigh frame 32; the side surface of the expected tank 31 is provided with a plurality of sliding grooves, the outer side of each sliding groove is respectively connected with a sliding block frame, the inner side surface of each sliding block frame is provided with a sliding block matched with the sliding groove, the lower end surface of each sliding block frame is connected with a weighing frame 32, and the expected tank 31 can slide up and down relative to the weighing frame 32 through the movable connection of the sliding grooves and the sliding block frames; a reinforcing rib is fixedly connected to the side face of the anticipating tank 31, and a weighing sensor is arranged between the lower end face of the reinforcing rib and the weighing frame 32.

Specifically, the number of the cement storage tanks 21 is 1, and the number of the sand storage tanks 22 is 3; the cement storage tank 21 and the sand storage tank 22 are arranged in parallel, the maximum storage capacity of the cement storage tank 21 is 60 tons, and the maximum storage capacity of the sand storage tank 22 is 30 tons. The upper end surface of the pre-tank 31 is provided with 4 automatic feed inlets, and the conveyors 23 to which the 1 cement storage tank 21 and 3 sand storage tanks 22 are connected are respectively connected to the automatic feed inlets at the upper end of the pre-tank 31 to perform automatic feeding.

As the preferable implementation of the utility model, the upper ends of the cement storage tank 21, the sand storage tank 22 and the anticipation tank 31 are respectively provided with a dust remover, and the dust remover ensures that the production quality of GRC and UHPC is more stable and is not easily influenced by external dust.

As a preferred implementation of the present utility model, the distributor block is driven by a cylinder provided outside the Y-shaped discharging frame 41, the distributor block includes two semicircular side surfaces and a rectangular bottom surface, and the distributor block can rotate around the arc top position of the semicircular side surfaces to adjust the inclination direction of the distributor block bottom surface.

As a preferred implementation of the present utility model, the charging tank 11 is a high-pressure pneumatic charging tank 11; the conveyor 23 is a screw conveyor; the stirring equipment is a vertical shaft planetary stirrer.

The high-pressure pneumatic feeding tank 11 can directly transmit raw materials of GRC to the upper end of the storage tank through high pressure, the spiral conveyor works stably, the weighing precision can reach 0.5%, and the high-pressure pneumatic feeding tank is matched with the Y-shaped discharging frame 41 with good sealing performance, so that the discharging of the utility model meets the production requirements of GRC and UHPC.

A control cabinet is also provided in the present utility model to control the precise operation of the feed assembly 1, the anticipation assembly 3, the divide assembly 4 and the agitation assembly 5. By arranging the control cabinet, the utility model can store different material formulas. Specifically, at least 10 different material formulas can be stored to adapt to different material production requirements, each material formula comprises the addition sequence and weighing characteristics of raw materials, when a user produces different materials, the user only needs to select the corresponding formula in a control cabinet, the control cabinet controls the materials to be sequentially added into the anticipating tank 31, and the weighing sensor on the weighing frame 32 feeds back the materials entering the anticipating tank 31 each time, so that the preparation of the different material formulas is realized, and the production requirements of different building materials are further met.

The working principle of the material conveying weighing and stirring system which is simultaneously applicable to GRC and UHPC is as follows:

the utility model is provided with the anticipation component 3, the distributing component 4 and the stirring component 5 which are sequentially connected from top to bottom, so that materials can be selectively distributed into the stirring device 51 after being anticipated and weighed, and precise feeding control is realized. In the GRC production, the materials in the cement storage tank 21 and the sand storage tank 22 can be respectively conveyed into the anticipation tank 31 in proportion, and are premixed and weighed to realize the feeding procedure of GRC production, and the manual feeding port 311 is arranged in the anticipation tank 31 of the anticipation assembly 3, so that the pre-synthesized raw materials can be directly poured into the anticipation tank 31 in the UHPC production. And two stirring devices 51 are provided in the stirring assembly 5, so that parallel independent processing of the GRC material and the UHPC material, or stirring processing of dry-wet separation can be realized.

Other structures of the material conveying weighing and stirring system which are applicable to GRC and UHPC simultaneously are described in the embodiment, and refer to the prior art.

The present utility model is not limited to the preferred embodiments, and any modifications, equivalent variations and modifications made to the above embodiments according to the technical principles of the present utility model are within the scope of the technical proposal of the present utility model.

Claims (10)

1. A material conveying, weighing and stirring system applicable to both GRC and UHPC, comprising:

the feeding assembly comprises a feeding tank;

the storage assembly comprises a cement storage tank and a sand storage tank, and the sand storage tank is connected with the feeding tank through a feeding pipe;

the predicting assembly comprises a predicting tank, wherein the cement storage tank and the sand storage tank are respectively connected with the predicting tank through a conveyor, and a manual feed inlet is further formed in the predicting tank;

the material distributing assembly comprises a Y-shaped discharging frame connected to the lower end of the expected tank, wherein a material distributing block is arranged in the Y-shaped discharging frame, and one outlet at the lower end of the Y-shaped discharging frame is selected by rotating the material distributing block;

the stirring assembly comprises two stirring devices, and the upper ends of the two stirring devices are respectively connected with one outlet of the Y-shaped discharging frame.

2. The simultaneous grac and UHPC feed weighing and stirring system of claim 1, wherein:

the feeding assembly further comprises a feeding travelling crane and a feeding room, wherein the feeding travelling crane is used for transporting the ware of the sand of the device to the feeding room;

the side of the feeding house is provided with an opening corresponding to the feeding travelling crane, and the lower end of the feeding house is communicated with the feeding tank.

3. The simultaneous grac and UHPC feed weighing and stirring system of claim 2, wherein:

the lower extreme of material loading room is provided with the feed inlet of hopper-shaped, the top of feed inlet is equipped with articulated feeding lid, the feed inlet with be provided with pneumatic valve between the material loading jar.

4. A simultaneous GRC and UHPC feed weighing and stirring system according to claim 3, further comprising:

the working platform comprises a first layer of platform and a second layer of platform, and stairs are arranged between the first layer of platform and the second layer of platform.

5. The simultaneous grac and UHPC feed weighing and stirring system of claim 4, wherein:

the feeding room is arranged on the first-layer platform, the anticipating tank is arranged on the second-layer platform, the material distribution assembly is arranged between the first-layer platform and the second-layer platform, and the stirring device is arranged on the first-layer platform;

the two-layer platform is provided with a through hole matched with the pre-charging tank, and the one-layer platform is provided with a funnel-shaped discharge hole adjacent to the stirring device.

6. The simultaneous grac and UHPC feed weighing and stirring system of claim 1, wherein:

a weighing frame is arranged on the periphery of the expected tank in a surrounding manner, and the expected tank penetrates through the weighing frame;

the side of the expected tank is provided with a plurality of sliding grooves, the outer side of each sliding groove is respectively connected with a sliding block frame, the inner side of each sliding block frame is provided with a sliding block matched with the sliding groove, the lower end face of each sliding block frame is connected with the weighing frame, and the expected tank can slide up and down relative to the weighing frame through the movable connection of the sliding grooves and the sliding block frames;

the side of expecting the jar fixedly connected with strengthening rib, be equipped with weighing sensor between the lower terminal surface of strengthening rib and the weighing frame.

7. The simultaneous grac and UHPC feed weighing and stirring system of claim 1, wherein:

the number of the cement storage tanks is 1, and the number of the sand storage tanks is 3;

cement storage tank with the maximum storage capacity of cement storage tank parallel arrangement, the maximum storage capacity of cement storage tank be 60 tons, the maximum storage capacity of sand storage tank be 30 tons.

8. The simultaneous grac and UHPC feed weighing and stirring system of claim 1, wherein:

the upper ends of the cement storage tank, the sand storage tank and the pre-material tank are respectively provided with a dust remover.

9. The simultaneous grac and UHPC feed weighing and stirring system of claim 1, wherein:

the distributing block is driven by an air cylinder arranged on the outer side of the Y-shaped discharging frame and comprises two semicircular side faces and a rectangular bottom face, and the distributing block can rotate around the arc top position of the semicircular side faces so as to adjust the inclination direction of the bottom face of the distributing block.

10. The simultaneous GRC and UHPC feed weighing and stirring system of any one of claims 1 to 8, wherein:

the feeding tank is a high-pressure pneumatic feeding tank;

the conveyor is a spiral conveyor;

the stirring device is a vertical shaft planetary stirrer.