CN111169025A - Ecological stone production distributing system - Google Patents

Abstract

The invention discloses a material distribution system for ecological stone production, which sequentially comprises a blanking device, a feeding device, a material distribution mold frame and a conveying device from top to bottom; the blanking device comprises a plurality of blanking hoppers and V-shaped flowing guide grooves, the blanking hoppers are arranged in parallel, the V-shaped flowing guide grooves are arranged below the blanking hoppers, and the feed inlets of the V-shaped flowing guide grooves are positioned right below the discharge outlets of the blanking hoppers; the feeding device comprises a feeding hopper and a feeding and supplementing rod, the feeding and supplementing rod is rotatably arranged on the inner side surface of the feeding hopper, and the rotation of the feeding and supplementing rod is used for realizing forward feeding or backward supplementing; the feeding hopper is arranged below the V-shaped flowing guide groove, and the feeding port of the feeding hopper is positioned right below the discharging port of the V-shaped flowing guide groove. The ecological stone production distribution system that this technical scheme provided is favorable to producing different mixed effect to the thick liquids, promotes the richness of texture pattern, improves ecological stone's imitative natural effect.

Description

Ecological stone production distributing system

Technical Field

The invention relates to the technical field of building ceramics, in particular to a material distribution system for ecological stone production.

Background

The surface of the ecological stone has the effect of natural stone, and the patterns can be changed variously. With the continuous development of social economy, the requirements of people on living quality and living environment are continuously improved, so that the decorative material with natural stone imitation, simplicity and nature is deeply loved by people.

The preparation of ecological stone among the prior art adopts bell jar to drench glaze device or straight line to drench glaze device and carries out the decoration of ecological stone face usually, nevertheless because drench thick liquid technology mode single, drench thick liquid regulation and control difficulty, the limitation that drenches thick liquid equipment leads to the limitation of surface decoration effect, still can influence the mixed effect of thick liquid, the blending degree of thick liquid is relatively poor, the level effect often is not obvious, the technological effect is simple and hard, and drench thick liquid unstability can lead to the pattern texture of the ecological stone that prepares to have clear lifelike, repetition single inadequately, the lines are hard, simple not enough.

In order to overcome the defects of the slurry spraying process in the preparation of the ecological stone, some ecological stone production enterprises begin to change the preparation mode of the ecological stone, the basic slurry with the basic tone of the stone slab and the color slurry with the decoration effect form mixed slurry through a mixing device, and the slurry is stirred by a stirring device to form a certain natural texture imitating pattern. Because the ecological stone produced by the process or the equipment mainly utilizes the material stirring device to form the texture patterns, and the stirring track of the material stirring device is single and has larger limitation, the natural imitation effect of the ecological stone prepared by the ecological stone is single and hard, so that the texture patterns of the ecological stone are not natural at all.

Disclosure of Invention

The invention aims to provide a material distribution system for ecological stone production, which is beneficial to generating different mixing effects on slurry, improving the richness of texture patterns and improving the natural imitation effect of the ecological stone.

In order to achieve the purpose, the invention adopts the following technical scheme:

the ecological stone production and distribution system sequentially comprises a blanking device, a feeding device, a distribution mold frame and a conveying device from top to bottom, wherein the blanking device is used for blanking to the feeding device, the feeding device is used for distributing to the distribution mold frame, and the conveying device 4 is used for conveying the distribution mold frame to a position right below the feeding device;

the blanking device comprises a plurality of blanking hoppers and a V-shaped flowing guide groove, the blanking hoppers are arranged in parallel, the V-shaped flowing guide groove is arranged below the blanking hoppers, and a feed inlet of the V-shaped flowing guide groove is positioned right below a discharge outlet of the blanking hoppers;

the feeding device comprises a feeding hopper and a feeding and supplementing rod, the feeding and supplementing rod is rotatably arranged on the inner side surface of the feeding hopper, and the feeding and supplementing rod rotates to feed forwards or supplement backwards; the feeding hopper is arranged below the V-shaped flowing guide groove, and the feeding port of the feeding hopper is positioned right below the discharging port of the V-shaped flowing guide groove.

Preferably, the feeding device comprises a distribution hopper, the distribution hopper is arranged below the discharge port of the feeding hopper, and the distribution hopper can swing back and forth along the length direction of the discharge port of the feeding hopper; the lowest point of the discharge hole of the distributing hopper can be connected with the top of the distributing die frame.

Preferably, the medial surface of cloth fill is equipped with a plurality of cloth boards that can independently move about, the cloth board along the flow direction of thick liquids install in the cloth fill, form the cloth clearance that is used for the thick liquids to flow between the cloth board, just the cloth board can be followed the length direction reciprocating swing of the discharge gate of hopper.

Preferably, the feeding hopper comprises a material blocking edge and a feeding table, the vertical section of the material blocking edge is arc-shaped, and the arc-shaped direction of the material blocking edge faces the discharge hole direction of the feeding hopper; the feeding table is integrally formed at the tail end of the material blocking edge, and the tail end of the feeding table is arranged in a downward inclined mode.

Preferably, helical blades are arranged on the rod wall of the feeding and material supplementing rod in a surrounding mode, and two adjacent helical blades located on the same plane are of a horn-shaped structure;

the material stopping device is characterized in that a material supplementing hole is formed in the tail end of the material stopping edge, the feeding material supplementing rod penetrates through the material supplementing hole to be installed on the feeding hopper, the driving end of the feeding material supplementing rod is connected with a feeding material supplementing driving device, and the feeding material supplementing driving device is used for driving the feeding material supplementing rod to rotate.

Preferably, the feeding device further comprises a feeding device, the feeding device comprises a feeding box, a feeding hopper and a fixed base, the feeding box is mounted between the material blocking edge and the feeding and feeding driving device, and the bottom of the feeding box is provided with a feeding port;

the material supplementing hopper is arranged below the material supplementing box through the fixed base, and the material supplementing opening of the material supplementing box is located right above the material feeding opening of the material supplementing hopper.

Preferably, the material supplementing hopper is provided with a fixed thick wall and a material supplementing wall, the fixed thick wall is positioned in the advancing direction of the material distributing mold frame, and the bottom edge of the fixed thick wall can be connected with the top of the material distributing mold frame; the material supplementing wall is opposite to the fixed thick wall, and the height of the bottom edge of the material supplementing wall is higher than that of the bottom edge of the fixed thick wall.

Preferably, the slurry stirring device further comprises a stirring device, the stirring device comprises an installation base, a stirring driving device and a stirring rod, the stirring driving device is installed above the distribution die frame through the installation base, the output end of the stirring driving device is connected with the stirring rod, the stirring driving device drives the stirring rod to stir, and the stirring rod is used for stirring the slurry of the feeding table.

Preferably, the V-shaped flow guide grooves are provided with a plurality of groups, and the V-shaped flow guide grooves are arranged in parallel along the length direction of the discharge hole of the discharge hopper.

Preferably, the V-shaped flow guide groove includes a first flow groove and a second flow groove, the first flow groove and the second flow groove are disposed in an inclined manner to form a mixing flow channel with a V-shaped cross section, and a discharge port of the first flow groove is located right above the second flow groove.

The invention has the beneficial effects that: the ecological stone production distribution system that this technical scheme provided is favorable to producing different mixed effect to the thick liquids, promotes the richness of texture pattern, improves ecological stone's imitative natural effect.

Drawings

The drawings are further illustrative of the invention and the content of the drawings does not constitute any limitation of the invention.

Fig. 1 is a schematic structural diagram of a distribution system for ecological stone production according to the invention.

Fig. 2 is a sectional view of a discharging hopper in the ecological stone production distributing system.

Fig. 3 is a side view of a lower hopper and a second flow groove in the ecological stone production distributing system.

FIG. 4 is a cross-sectional view of a V-shaped flow guide groove in the distribution system for ecological stone production.

Wherein:

the blanking device 1, the blanking hopper 11, the stirring rod 111, the stirring driving device 112, the V-shaped flow guide groove 12, the first flow groove 121, the second flow groove 122, the flow guide groove 123, the handle 1231, the flow guide sheet 1232, the flow guide grid 124, the rotating shaft 125, the baffle plate assembly 13, the blanking plate 131, the blanking driving device 132 and the blanking guide groove 14;

the feeding device 2, the feeding hopper 21, the material blocking edge 211, the feeding table 212, the feeding and supplementing rod 22, the feeding and supplementing driving device 222, the helical blade 221, the distributing mold frame 3, the conveying device 4, the distributing hopper 5, the distributing plate 51, the supplementing device 6, the supplementing box 61, the supplementing hopper 62, the fixed thick wall 621, the supplementing wall 622, the fixed base 63, the material stirring device 7, the mounting base 71, the guide rail 711, the material stirring driving device 72, the material stirring rod 73, the sliding base 74, the guide strip 741 and the rotating base 75.

Detailed Description

The technical scheme of the invention is further explained by the specific implementation mode in combination with the attached drawings.

The ecological stone production and distribution system sequentially comprises a blanking device 1, a feeding device 2, a distribution mold frame 3 and a conveying device 4 from top to bottom, wherein the blanking device 1 is used for blanking to the feeding device 2, the feeding device 2 is used for distributing to the distribution mold frame 3, and the conveying device 4 is used for conveying the distribution mold frame 3 to a position right below the feeding device 2;

the blanking device 1 comprises a plurality of blanking hoppers 11 and V-shaped flowing guide grooves 12, the blanking hoppers 11 are arranged in parallel, the V-shaped flowing guide grooves 12 are arranged below the blanking hoppers 11, and the feed inlets of the V-shaped flowing guide grooves 12 are positioned right below the discharge outlets of the blanking hoppers 11;

the feeding device 2 comprises a feeding hopper 21 and a feeding and supplementing rod 22, the feeding and supplementing rod 22 is rotatably arranged on the inner side surface of the feeding hopper 21, and the feeding and supplementing rod 22 rotates to realize forward feeding or backward supplementing; the hopper 21 is arranged below the V-shaped flowing guide groove 12, and the feeding port of the hopper 21 is positioned right below the discharging port of the V-shaped flowing guide groove 12.

In the prior art, the preparation process of ecological stone generally forms mixed slurry by using a mixing device to mix basic slurry with stone slab basic tone and color slurry with a decoration effect, and stirs the slurry by using a stirring device to form a certain imitated natural texture pattern. However, the ecological stone produced by the process or the equipment mainly utilizes the material stirring device to form the texture patterns, and the stirring track of the material stirring device is single and has great limitation, so the natural imitation effect of the ecological stone prepared by the ecological stone is single and hard, and the texture patterns of the ecological stone are not natural at all.

In order to improve the richness of texture patterns and improve the natural imitation effect of ecological stones, the technical scheme provides a material distribution system for ecological stones, which comprises a blanking device 1, a feeding device 2, a material distribution mold frame 3 and a conveying device 4.

The working process of the material distribution system in the technical scheme is as follows: the lower hopper 11 is filled with basic slurry or color slurry, and the two types of slurry can fall onto the V-shaped flowing guide groove 12 after being discharged from the lower hopper 11 at different discharging speeds, different discharging amounts or different discharging times, so that different mixing effects are generated; then the slurry falls into a feeding hopper 21 through the conduction of the V-shaped flowing guide groove 12, and the mixed slurry can generate different mixed textures through the rotation of a feeding and supplementing rod 22 on the feeding hopper 21; finally, the material with mixed texture is gradually applied to the material distribution mold frame 3 and is conveyed out of the material distribution system by the conveying device 4.

According to the technical scheme, different discharging speeds, different discharging amounts or different discharging times of the basic slurry or the color slurry in the discharging hopper 11 are controlled, so that the discharging proportion of different slurries is controlled, different mixing effects of the slurries are facilitated, the texture richness is improved, and the nature of color and texture mixing change is facilitated; secondly, this technical scheme still is equipped with rotatable pay-off benefit pole 22 in hopper 21, and concretely, pay-off benefit pole 22 can be forward, can reverse, can be intermittent type, can be continuous, can slow speed or can rotate fast and stir thick liquids, can make mixed thick liquids produce different mixed texture, further improves the abundance of texture. Because no matter through control basic thick liquids or color paste different unloading speed, different unloading volume or different unloading time in hopper 11 down, thereby make the thick liquids produce different mixed effect, still stir the thick liquids through setting up pay-off benefit pole 22, thereby make mixed thick liquids produce different mixed texture, this technical scheme all makes the thick liquids produce the texture pattern through the mode that the guide thick liquids flow, consequently the texture pattern transition of formation is natural, thereby can make the ecological stone that forms can accord with the texture of natural stone more, be favorable to improving the imitative natural effect of ecological stone.

Further, the feeding device 2 comprises a distribution hopper 5, the distribution hopper 5 is arranged below the discharge port of the feeding hopper 21, and the distribution hopper 5 can swing back and forth along the length direction of the discharge port of the feeding hopper 21; the lowest point of the discharge hole of the distributing hopper 5 can be connected with the top of the distributing die frame 3.

Cloth 5 fill can follow the length direction reciprocating swing of the discharge gate of hopper 21, can effectively increase the continuity of thick liquids cloth, form twill, continuity texture such as raised grain, be favorable to increasing the curtain coating effect of different colour thick liquids, the minimum of the discharge gate of cloth 5 fill can meet in the top of cloth framed 3, can effectively control cloth 5 fill material level and keep the continuity and the stability of texture, be favorable to improving the suppression stability and the suppression density of thick liquids in the cloth framed 3 simultaneously.

Further, a plurality of independently movable distributing plates 51 are arranged on the inner side surface of the distributing hopper 5, the distributing plates 51 are mounted on the distributing hopper 5 along the flowing direction of the slurry, a distributing gap for the slurry to flow is formed between the distributing plates 51, and the distributing plates 51 can swing back and forth along the length direction of the discharge port of the hopper 21.

Be equipped with a plurality of cloth plates 51 that can independently move about at the medial surface of cloth hopper 5, and cloth plate 51 can follow the length direction reciprocating swing of the discharge gate of hopper 21, when the swing of partial cloth plate 51 among control cloth hopper 5, selectively increase the continuity that this part corresponds the thick liquids cloth, be favorable to increasing the curtain coating effect of the colour thick liquids of different parts in same ecological stone to improve the texture pattern abundance of imitative ecological stone.

More specifically, the hopper 21 comprises a material blocking edge 211 and a feeding table 212, the vertical section of the material blocking edge 211 is arc-shaped, and the material blocking edge 211 faces the discharge hole of the hopper 21 along the arc-shaped direction; the feeding table 212 is integrally formed at the tail end of the material blocking edge 211, and the tail end of the feeding table 212 is arranged in a downward inclined mode.

The feeding hopper 21 comprises a blocking edge 211 and a feeding table 212, the blocking edge 211 with an arc structure is beneficial to preventing the slurry from flowing to other places except the feeding hopper 21, and meanwhile, the slurry is prevented from splashing out of the feeding hopper 21 when falling; the feeding table 212 is integrally formed at the tail end of the material blocking edge 211, and the tail end of the feeding table 212 is inclined downwards, so that slurry flows along the feeding table 212 under the action of gravity, and the flowability of the slurry is improved.

Further, the spiral blades 221 are surrounded on the rod wall of the feeding and feeding rod 22, and two adjacent spiral blades 221 located on the same plane are in a horn-shaped structure;

the tail end of the material blocking edge 211 is provided with a material supplementing hole, the feeding material supplementing rod 22 passes through the material supplementing hole and is installed on the feeding hopper 21, the driving end of the feeding material supplementing rod 22 is connected with a feeding material supplementing driving device 222, and the feeding material supplementing driving device 222 is used for driving the feeding material supplementing rod 22 to rotate.

The spiral blades 221 are arranged around the rod wall of the feeding and supplementing rod 22, two adjacent spiral blades 221 located on the same plane are of a horn-shaped structure, when the feeding and supplementing driving device 222 controls the spiral blades 221 of the feeding and supplementing rod 22 to rotate towards the discharge port of the hopper 21, slurry flows towards the discharge port of the hopper 21 under the extrusion of the spiral blades 221 of the horn-shaped structure, and at the moment, the feeding and supplementing rod 22 plays a feeding role; when the feeding and supplementing driving device 222 controls the spiral blade 221 of the feeding and supplementing rod 22 to rotate towards the supplementing hole direction of the hopper 21, slurry flows towards the supplementing hole direction of the hopper 21 under the extrusion of the spiral blade 221 with the horn-shaped structure, and at the moment, the feeding and supplementing rod 22 plays a supplementing role.

The slurry discharged from the material supplementing hole can fall on the advancing distributing mold frame 3, so that the slurry can be favorably distributed on the mold, and the distributing weight is stabilized.

In a further description, the feeding device 6 is further included, the feeding device 6 includes a feeding box 61, a feeding hopper 62 and a fixed base 63, the feeding box 61 is installed between the material blocking edge 211 and the feeding and feeding driving device 222, and a feeding port is formed at the bottom of the feeding box 61;

the material supplementing hopper 62 is arranged below the material supplementing box 61 through the fixed base 63, and the material supplementing opening of the material supplementing box 61 is positioned right above the material inlet of the material supplementing hopper 62.

The feeding device 6 comprises a feeding box 61, a feeding hopper 62 and a fixed base 63, the feeding box 61 is arranged between the stopping edge 211 and the feeding and feeding driving device 222, and when the feeding and feeding driving device 222 controls the spiral blade 221 of the feeding and feeding rod 22 to rotate towards the feeding hole of the feeding hopper 21, the feeding and feeding driving device is beneficial to collecting slurry discharged through the feeding hole; the material supplementing box 62 is arranged below the material supplementing box 61 through the fixing base 63, the material supplementing opening of the material supplementing box 61 is located right above the material inlet of the material supplementing box 62, and the collected slurry enters the material supplementing box 62, so that the slurry is supplemented to the material distributing mold frame 3 through the material supplementing box 62.

Preferably, the inside of the material supplementing hopper 62 is provided with a stirring rod, the outside of the material supplementing hopper 62 is provided with a stirring driving device, the output end of the stirring driving device is connected with the stirring rod, the stirring driving device drives the stirring rod, and the stirring rod is used for stirring the slurry in the material supplementing hopper 62.

The stirring driving device (not shown) drives a stirring rod (not shown), and the stirring rod is used for stirring the slurry in the feed supplement hopper 62, so that the slurry fluidity can be maintained, and the slurry discharging uniformity and stability can be ensured.

Further, the material supplementing hopper 62 is provided with a fixed thick wall 621 and a material supplementing wall 622, the fixed thick wall 621 is located in the advancing direction of the material distributing mold frame 3, and the bottom edge of the fixed thick wall 621 can be connected to the top of the material distributing mold frame 3; the supplement wall 622 is opposite to the fixed thick wall 621, and the height of the bottom edge of the supplement wall 622 is higher than that of the fixed thick wall 621.

The material supplementing hopper 62 is provided with a fixed thick wall 621 and a material supplementing wall 622, the fixed thick wall 621 is located in the advancing direction of the material distributing mold frame 3, and the bottom edge of the fixed thick wall 621 can be connected to the top of the material distributing mold frame 3, so that the improvement of the pressing stability and the pressing density of the slurry in the material distributing mold frame 3 after material supplementing is facilitated. The material supplementing wall 622 is opposite to the fixed thick wall 621, and the height of the bottom edge of the material supplementing wall 622 is higher than that of the bottom edge of the fixed thick wall 621, so that smooth discharging of slurry is facilitated.

Further, the material stirring device 7 is further included, the material stirring device 7 includes an installation base 71, a material stirring driving device 72 and a material stirring rod 73, the material stirring driving device 72 is installed above the material distribution mold frame 3 through the installation base 71, an output end of the material stirring driving device 72 is connected with the material stirring rod 73, the material stirring driving device 72 drives the material stirring rod 73 to stir, and the material stirring rod 73 is used for stirring the slurry of the feeding table 212.

The technical scheme is that the material stirring device 7 is additionally arranged, the material stirring driving device 72 drives the material stirring rod 73 to stir, so that the material stirring rod can stir the slurry of the feeding table 212, and an operator can control the material stirring driving device 72 through software, thereby being beneficial to realizing variable textures and special textures in ecological stones.

Preferably, the material stirring device 7 further comprises a sliding base 74, the material stirring driving device 72 is mounted on the top of the sliding base 74, and the sliding base 74 is slidably mounted on the mounting base 71; a guide rail 711 is arranged at the top of the mounting base 71, a guide strip 741 is arranged at the bottom of the sliding base 74, and the guide strip 741 can slide along the guide rail 711.

The material stirring device 7 comprises a sliding base 74, a guide rail 711 is arranged at the top of the mounting base 71, a guide strip 741 is arranged at the bottom of the sliding base 74, and the guide strip 741 can slide along the guide rail 711, so that the sliding base 74 can be slidably mounted on the mounting base 71, the movement flexibility of the material stirring device 7 is improved, the material stirring range of the material stirring rod 73 is increased, and the texture richness of ecological stones is improved.

Preferably, the material stirring device 7 further includes a rotating base 75, the rotating base 75 is disposed between the sliding base 74 and the material stirring driving device 72, a rotating driving device is disposed inside the rotating base 75, and the material stirring driving device 72 can rotate relative to the sliding base 74 through the rotating base 75.

The material stirring device 7 further comprises a rotating base 75, and the material stirring driving device 72 can rotate relative to the sliding base 74 through the rotating base 75, so that the moving flexibility of the material stirring device 7 is improved, the material stirring range of the material stirring rod 73 is effectively increased, and the texture richness of ecological stones is improved.

More specifically, the V-shaped flow guide grooves 12 are provided in multiple sets, and the multiple sets of V-shaped flow guide grooves 12 are arranged in parallel along the length direction of the discharge hole of the discharge hopper 11.

In an embodiment of this technical scheme, V type flow guide slot 12 is equipped with the multiunit, and multiunit V type flow guide slot 12 sets up side by side along the length direction of the discharge gate of hopper 11 down, and after the unloading of hopper 11, drop on material feeding device 2 again after the thick liquids follow down the unloading of hopper, through the mixing of different V type flow guide slots 12, more be favorable to thick liquids multiple mode ground to mix, promote the mixed effect of thick liquids to improve ecological stone texture pattern's abundance.

Further, the V-shaped flow guiding groove 12 includes a first flow groove 121 and a second flow groove 122, the first flow groove 121 and the second flow groove 122 are disposed in an inclined manner to form a mixing flow channel with a V-shaped cross section, and a discharge port of the first flow groove 121 is located right above the second flow groove 122.

The basic slurry and the color slurry are firstly discharged from a discharging hopper 11 at different discharging speeds, different discharging amounts or different discharging times, and then fall into a V-shaped flowing guide groove 12 to form first mixing of the slurry; the first flow groove 121 and the second flow groove 122 are used for flowing and mixing the slurry, and then the mixed slurry can be further fused with each other through the joint of the first flow groove 121 and the second flow groove 122, so that a richer mixing effect is generated, the mixing is uniform, and the transition is natural.

Preferably, the blanking device 1 further includes a guide groove 123, and the guide groove 123 is detachably mounted to the first flow groove 121 and/or the second flow groove 122.

The guide groove 123 is detachably installed in the first flow groove 121 and/or the second flow groove 122, and after the distribution system finishes distributing the slurry, the guide groove 123 can be detached from the first flow groove 121 and/or the second flow groove 122, so that the V-shaped flow guide groove 12 can be conveniently cleaned.

Preferably, a handle 1231 protrudes from a top end of the guide groove 123, and the handle 1231 is used for mounting or dismounting the guide groove 123.

The handle 1231 is protrudingly disposed at the top end of the guide groove 123, so that an operator can conveniently mount or dismount the guide groove 123, and meanwhile, due to the protrusive arrangement of the handle 1231, the guide groove 123 can be stably mounted on the first flow groove 121 and/or the second flow groove 122.

Preferably, the handle 1231 has a plate-shaped structure, the handle 1231 is perpendicular to the bottom plate of the guiding groove 123, and the direction of the handle 1231 faces the bottom surface of the guiding groove 123.

Handle 1231 is platelike structure, makes things convenient for operating personnel's the grabbing to take, and handle 1231 perpendicular to guiding gutter 123's bottom plate, and handle 1231's direction is towards the bottom surface of guiding gutter 123, is favorable to preventing that handle 1231 from sheltering from the feed inlet of V type flow guide slot 12, is favorable to the smooth unloading of thick liquids, still is favorable to operating personnel to observe the mixed condition of thick liquids from the feed inlet of V type flow guide slot 12 simultaneously, at any time to the mixed condition countermeasures of thick liquids.

Preferably, a baffle 1232 protrudes from a surface of the bottom plate of the guiding channel 123, and the baffle 1232 is used for guiding the flow of the slurry in the guiding channel 123.

The surface of the bottom plate of the guiding groove 123 is protrudingly provided with a guiding sheet 1232, and the slurry can flow randomly in the guiding groove 123 under the guidance of the guiding sheet 1232, so that the texture of the ecological stone is further enriched. Furthermore, the slurry is enabled to generate texture patterns in a mode of guiding the slurry to flow, and the formed texture patterns are transited naturally, so that the formed ecological stone can better accord with the texture of natural stone, and the natural imitation effect of the ecological stone is further improved.

Preferably, the blanking device 1 further comprises a flow guide grid 124, and the flow guide grid 124 is detachably mounted on the discharge port of the first flow groove 121 and/or the second flow groove 122.

The flow guide grids 124 have the function of shunting the slurry, when the slurry in the V-shaped flow guide groove 12 falls to the feeding hopper 21 through the flow guide grids 124, the slurry is separated and then mixed, the slurry is fully mixed, and therefore the mixing effect of the mixed slurry is improved.

Preferably, the top end of the first flow groove 121 and/or the second flow groove 122 is provided with a rotating shaft 125 and a rotation driving device, the top end of the first flow groove 121 and/or the second flow groove 122 is connected to the output end of the rotation driving device, the rotation driving device drives the first flow groove 121 and/or the second flow groove 122, and the first flow groove 121 and/or the second flow groove 122 can rotate relative to the rotating shaft 125.

The rotation driving device drives the first flow groove 121 and/or the second flow groove 122 to enable the first flow groove 121 and/or the second flow groove 122 to rotate relative to the rotation shaft 125, so that an operator can conveniently adjust the inclination angles of the first flow groove 121 and the second flow groove 122, and the adjustment of the blanking speed of the slurry in the blanking device 1 is facilitated, and the distribution beat of the distribution system is controlled.

Preferably, the blanking device 1 is further provided with a plurality of groups of baffle assemblies 13, the plurality of groups of baffle assemblies 13 are arranged in parallel along the length direction of the discharge hole of the blanking hopper 11, and the arrangement positions of the baffle assemblies 13 correspond to the arrangement positions of the V-shaped flow guide grooves 12 one by one;

the baffle assembly 13 includes a plurality of blanking plates 131 and a blanking driving device 132, the blanking plates 131 are covered on the discharge port of the blanking hopper 11, and the blanking driving device 132 drives the blanking plates 131 to open or close, so that the discharge port of the blanking hopper 11 forms a plurality of open or closed blanking holes.

The blanking driving device 132 drives the blanking plate 131 to open or close, so that a plurality of opened or closed blanking holes are formed at the discharge port of the blanking hopper 11, the arrangement of the baffle plate assembly 13 is favorable for improving blanking controllability of different slurries in the blanking hopper 11, and is favorable for controlling the blanking plate 131 to open or close, thereby controlling different blanking amounts or blanking time of the slurries, being favorable for adjusting adding proportions of different slurries in mixed slurry, realizing different texture patterns in ecological stones, and improving applicability of a material distribution system.

Preferably, a stirring rod 111 is installed inside the lower hopper 11, a stirring driving device 112 is installed outside the lower hopper 11, an output end of the stirring driving device 112 is connected with the stirring rod 111, and the stirring driving device 112 drives the stirring rod 111;

spiral blades 221 are arranged on the wall of the stirring rod 111 in a surrounding mode, two adjacent spiral blades 221 located on the same plane are of a horn-shaped structure, and the stirring rod 111 is used for stirring and discharging slurry in the discharging hopper 11.

The stirring rod 111 is installed inside the lower hopper 11, and the stirring driving device 112 drives the stirring rod 111, so that on one hand, the stirring rod 111 is used for stirring the slurry in the lower hopper 11, which is beneficial to preventing the slurry from solidifying, maintaining the fluidity of the slurry and ensuring the uniform mixing of the slurry in the lower hopper 11.

On the other hand, because the spiral blades 221 are arranged around the wall of the stirring rod 111, and two adjacent spiral blades 221 located on the same plane are in a horn-shaped structure, when the stirring rod 111 rotates, slurry can be extruded by the spiral blades 221 in the horn-shaped structure to be forcibly discharged from the discharging hopper 11, so that the stirring rod 111 has a function of forcibly discharging the slurry, and smooth discharging of the slurry is ensured; in addition, the operator can also control the rotation speed of the stirring rod through the stirring driving device 112, so as to control the blanking speed of the slurry in the non-blanking hopper 11, thereby generating different mixing effects.

Preferably, at least two stirring rods 111 are provided, and the two stirring rods 111 are vertically arranged inside the lower hopper 21 along the discharging direction of the slurry.

Preferably, the blanking device 1 is further provided with a blanking guide groove 14, the blanking guide groove 14 is arranged above the blanking hopper 11, and a discharge hole of the blanking guide groove 14 is located right above a feed hole of the blanking hopper 11.

The blanking device 1 is further provided with a blanking guide groove 14, the blanking guide groove 14 is arranged above the blanking hopper 11, a discharge hole of the blanking guide groove 14 is located right above a feed port of the blanking hopper 11, when basic slurry or color slurry needs to be poured into the blanking hopper 11, the slurry can be poured into the blanking guide groove 14, pouring of the slurry is facilitated, and the slurry is prevented from being poured into other places outside the blanking hopper 11.

The technical principle of the present invention is described above in connection with specific embodiments. The description is made for the purpose of illustrating the principles of the invention and should not be construed in any way as limiting the scope of the invention. Based on the explanations herein, those skilled in the art will be able to conceive of other embodiments of the present invention without inventive effort, which would fall within the scope of the present invention.

Claims (10)

1. The utility model provides an ecological stone produces cloth system which characterized in that: the cloth die frame comprises a blanking device, a feeding device, a cloth die frame and a conveying device from top to bottom in sequence, wherein the blanking device is used for blanking the feeding device, the feeding device is used for distributing the cloth to the cloth die frame, and the conveying device 4 is used for conveying the cloth die frame to the position right below the feeding device;

the blanking device comprises a plurality of blanking hoppers and a V-shaped flowing guide groove, the blanking hoppers are arranged in parallel, the V-shaped flowing guide groove is arranged below the blanking hoppers, and a feed inlet of the V-shaped flowing guide groove is positioned right below a discharge outlet of the blanking hoppers;

the feeding device comprises a feeding hopper and a feeding and supplementing rod, the feeding and supplementing rod is rotatably arranged on the inner side surface of the feeding hopper, and the feeding and supplementing rod rotates to feed forwards or supplement backwards; the feeding hopper is arranged below the V-shaped flowing guide groove, and the feeding port of the feeding hopper is positioned right below the discharging port of the V-shaped flowing guide groove.

2. The ecological stone production distribution system of claim 1, wherein: the feeding device comprises a distribution hopper, the distribution hopper is arranged below the discharge port of the feeding hopper, and the distribution hopper can swing back and forth along the length direction of the discharge port of the feeding hopper; the lowest point of the discharge hole of the distributing hopper can be connected with the top of the distributing die frame.

3. The ecological stone production distribution system of claim 2, wherein: the medial surface of cloth fill is equipped with a plurality of cloth plates that can independently move about, the cloth plate along the flow direction of thick liquids install in the cloth fill, form the cloth clearance that is used for the thick liquids to flow between the cloth plate, just the cloth plate can be followed the length direction reciprocating swing of the discharge gate of hopper.

4. The ecological stone production distribution system of claim 1, wherein: the feeding hopper comprises a material blocking edge and a feeding table, the vertical section of the material blocking edge is arc-shaped, and the arc-shaped direction of the material blocking edge faces the direction of a discharge hole of the feeding hopper; the feeding table is integrally formed at the tail end of the material blocking edge, and the tail end of the feeding table is arranged in a downward inclined mode.

5. The ecological stone production distribution system of claim 4, wherein: spiral blades are arranged on the rod wall of the feeding and material supplementing rod in a surrounding mode, and two adjacent spiral blades located on the same plane are of horn-shaped structures;

the material stopping device is characterized in that a material supplementing hole is formed in the tail end of the material stopping edge, the feeding material supplementing rod penetrates through the material supplementing hole to be installed on the feeding hopper, the driving end of the feeding material supplementing rod is connected with a feeding material supplementing driving device, and the feeding material supplementing driving device is used for driving the feeding material supplementing rod to rotate.

6. The ecological stone production distribution system of claim 5, wherein: the feeding and supplementing device comprises a material supplementing box, a material supplementing hopper and a fixed base, wherein the material supplementing box is arranged between the material blocking edge and the feeding and supplementing driving device, and the bottom of the material supplementing box is provided with a material supplementing opening;

the material supplementing hopper is arranged below the material supplementing box through the fixed base, and the material supplementing opening of the material supplementing box is located right above the material feeding opening of the material supplementing hopper.

7. The ecological stone production distribution system of claim 6, wherein: the material supplementing hopper is provided with a fixed thick wall and a material supplementing wall, the fixed thick wall is positioned in the advancing direction of the material distributing mold frame, and the bottom edge of the fixed thick wall can be connected with the top of the material distributing mold frame; the material supplementing wall is opposite to the fixed thick wall, and the height of the bottom edge of the material supplementing wall is higher than that of the bottom edge of the fixed thick wall.

8. The ecological stone production distribution system of claim 4, wherein: the material stirring device comprises an installation base, a material stirring driving device and a material stirring rod, the material stirring driving device is installed above the cloth mold frame through the installation base, the output end of the material stirring driving device is connected with the material stirring rod, the material stirring driving device drives the material stirring rod to stir, and the material stirring rod is used for stirring the slurry of the feeding table.

9. The ecological stone production distribution system of claim 1, wherein: the V-shaped flow guide grooves are provided with a plurality of groups, and the V-shaped flow guide grooves are arranged in parallel along the length direction of the discharge hole of the discharge hopper.

10. The ecological stone production distribution system of claim 9, wherein: the V-shaped flow guide groove comprises a first flow groove and a second flow groove, the first flow groove and the second flow groove are arranged in an inclined mode to form a mixing flow channel with a V-shaped section, and a discharge hole of the first flow groove is located right above the second flow groove.

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