CN112246161A

CN112246161A - Sand and stone conveyer

Info

Publication number: CN112246161A
Application number: CN202011029922.7A
Authority: CN
Inventors: 不公告发明人
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-09-27
Filing date: 2020-09-27
Publication date: 2021-01-22

Abstract

The application provides a grit conveyer. The sand-stone conveyer comprises a frame, sand-stone transporting and mixing equipment, air supply equipment, water supply equipment and vibration equipment. The sand and stone transporting and mixing device is flexibly connected with the frame and is provided with a feeding hole, a discharging hole, a wind inlet and a high-pressure water inlet. The air supply equipment is arranged on the frame and connected with the wind power inlet. The water supply equipment is arranged on the frame and is connected with the high-pressure water inlet. The vibrating equipment is arranged on the frame and connected with the sand conveying and mixing equipment so as to vibrate. Wherein, the inside mixed board that disposes of grit transportation and mixing apparatus, mixed board slope sets up, forms to high-end and to the low side, and the feed inlet is located to high-end, and the discharge gate is located to the low side, and wind-force import and high pressure water import are in to high-end and to the low side between, are formed with the through-hole on the mixed board to make rivers and air current pass through, act on the grit. Grit conveyer can promote the quality of grit at the in-process of transportation grit.

Description

Sand and stone conveyer

Technical Field

The application relates to grit transportation field particularly, relates to a grit conveyer.

Background

The conveyer is also called as a conveyer and is suitable for horizontal conveying, inclined conveying, vertical conveying and other forms of granular or powdery materials. The transport distance varies from model to model, and is generally from 2 meters to 70 meters.

Typically, the sand is transported by conveyors, however, existing conveyors only serve the purpose of transportation.

Disclosure of Invention

The application provides a grit conveyer, its in-process that can transport the grit promotes the quality of grit.

The invention is particularly such that:

grit conveyer includes:

a frame;

the sand and stone transporting and mixing device is in flexible connection with the rack and is provided with a feeding hole, a discharging hole, a wind inlet and a high-pressure water inlet;

the air supply equipment is arranged on the frame and is connected with the wind power inlet;

the water supply equipment is arranged on the frame and is connected with the high-pressure water inlet; and

the vibrating equipment is arranged on the rack and connected with the sand and stone transporting and mixing equipment so as to vibrate the sand and stone transporting and mixing equipment;

wherein, the inside mixed board that disposes of grit transportation and mixing apparatus, mixed board slope sets up, forms to high-end and to the low side, and the feed inlet is located to high-end, and the discharge gate is located to the low side, and wind-force import and high pressure water import are in to high-end and to the low side between, are formed with the through-hole on the mixed board to make rivers and air current pass through, act on the grit.

In the implementation process, the sand-stone conveyor is used for transporting sand-stones and simultaneously mixing, colliding and rubbing the sand and the stones, so that the sizes of the sand and the stones are consistent, the quality of the sand-stones is improved, and the utilization rate of the sand-stones is improved; the sand and stone mixture is thrown to the feeding hole to enter the sand and stone transporting and mixing device, the vibration device, the air supply device and the water supply device are started to respectively vibrate the sand and stone transporting and mixing device to generate a vibration power field, high-pressure air is sprayed out of the sand and stone transporting and mixing device to generate a wind power flow field, high-pressure water flow is sprayed into the sand and stone transporting and mixing device to generate a hydraulic flow field, the wind power flow field and the hydraulic flow field act on the sand and stone mixture through the through hole formed on the mixing plate, the sand and the stone are collided and rubbed with each other under the combined action of a vibration force field, a hydraulic flow field and a wind flow field, and particularly, under a vibration force field, the sand and the stones can be continuously thrown from a high end to a low end, and meanwhile, the sand and the stones can be continuously rubbed due to bumping on the mixing plate so as to change the size of the stones and enable the stones to approach the sand; meanwhile, the hydraulic flow field and the wind flow field can intensify the collision violence degree of the sand and the stones, and slow down the speed of the stones and the sand flowing to the low end, so that the stones and the sand are crushed in sand and stone transportation and mixing equipment for a long time; meanwhile, the transportation and the crushing of the sand and the stones are carried out in sand transportation and mixing equipment, and dust can not be raised due to the existence of a hydraulic flow field, so that the environment is protected; it should be noted that the sand mixture that is eventually crushed flows out of the discharge opening with a part of the water flow.

Optionally, in one possible implementation:

the sand and stone transporting and mixing device comprises a shell, two ends of the shell are inclined downwards and respectively form a feeding hole and a discharging hole;

the wind power inlet and the high-pressure water inlet are arranged between the feed inlet and the discharge outlet, and the wind power inlet and the high-pressure water inlet are both directed to the vertical center line of the shell;

a drain pipe is disposed at the bottom of the casing.

In the implementation process, the sand-gravel mixture is discharged into the sand-gravel transportation and mixing equipment from the lower part to the higher part, so that the speed of the sand-gravel mixture entering the sand-gravel transportation and mixing equipment is favorably reduced, and the energy of the sand-gravel mixture passing through the sand-gravel transportation and mixing equipment mainly comes from the common acting force of the gravity, a vibration force field, a hydraulic flow field and a wind flow field of the sand-gravel mixture, so that the sand-gravel mixture is fully acted by the vibration force field, the hydraulic flow field and the wind flow field, the aim of uniformly crushing and mixing is fulfilled, and the utilization rate and the quality of the; meanwhile, the discharge port faces downwards, so that the sandstone mixture can be discharged smoothly, and excessive crushing is avoided; simultaneously, because the grit mixture is broken and the transportation on the mixing plate, the event casing can dispose the drain pipe, does benefit to the discharge of rivers, avoids a large amount of water to mix the grit and discharges to reduce the degree of difficulty of later stage screening out grit.

Optionally, in one possible implementation:

the hybrid sheet includes a plurality of collision sections, and a plurality of collision sections set up along the direction interval in proper order to the low end to high end, and the collision section is followed and is inclined downwards to the direction of low end to high end.

In the process of the realization, when the mixing plate acts on the sand-gravel mixture, the vibration force field, the hydraulic flow field and the wind flow field act on the mixing plate, the air flow in the wind flow field and the water flow in the water flow field act on the sand and the stones to flow out through the through holes of the mixing plate, and the vibration force field can lead the mixing plate to vibrate. The sand and the stones on the mixing plate jump under the action of the vibration power field, and under the mutual collision of the sand and the stones, the sand and the stones also move from one collision section to the next collision section, so that the sand and the stones are continuously contacted with the collision sections and send collision; meanwhile, the sand with light jumping quality can be close to the middle part of the sand and stone transporting and mixing equipment under the action of the airflow and the water flow flowing out from the through hole, a turbulent air-water mixture is formed in the middle part, and the stone on the collision section can be continuously rubbed under the action of the airflow and the water flow (the collision section also plays a role in blocking the movement of the stone), so that the friction efficiency of the stone and the sand is improved, and the stone and the sand can be finally discharged from the discharge hole under the action of gravity.

Optionally, in one possible implementation:

the mixing plate also comprises a connecting section, and two adjacent collision sections are connected by the connecting section;

the connecting section is obliquely arranged;

wherein, the contained angle between linkage segment and the collision section is less than 90 degrees, and all is formed with the through-hole between linkage segment and the collision mouth section.

In the implementation process, the collision sections are smoothly connected through the connecting sections so as to ensure the structural strength of the mixing plate and avoid the crushing of the mixing plate caused by the action of a vibration power field, a hydraulic flow field and a wind power flow field on the mixing plate;

meanwhile, due to the existence of the connecting section, the sand-stone mixture can smoothly move from high end to low end, and the smooth transportation of sand-stone is ensured;

simultaneously, because the slope sets up between linkage segment and the collision section to and all be formed with the through-hole, so do benefit to the direction of air current and rivers, form a turbulent air-water mixture in the middle part of grit transportation and mixing apparatus.

Optionally, in one possible implementation:

the mixing plate further comprises a stabilizing section, wherein the stabilizing section is arranged at one end of the collision section facing to the high end and connected to the connecting section, and the stabilizing section and the connecting section are mutually vertical.

Above-mentioned in-process of realizing, the grit mixture can break away from the phenomenon in the mixing plate because the change of direction of motion after the collision section, for guaranteeing that the grit mixture is stably on the mixing plate, has increased the stable section to guarantee that the grit mixture can get back to the mixing plate again in the short time under its action of gravity.

Optionally, in one possible implementation:

the mixing plate is also provided with a mounting plate which is triangular, the inclined plane of the mounting plate is connected with the mixing plate, and the right-angle surface of the mounting plate is connected with the shell, so that the mixing plate is stably placed in the shell.

In the process of realizing, the triangular mounting plate is additionally arranged for simultaneously ensuring the inclined arrangement of the mixing plate and the horizontal stability of the sand and stone transportation and mixing equipment, and the normal transportation of a wind flow field and a hydraulic flow process to the mixing plate is ensured.

Optionally, in one possible implementation:

the vibration equipment comprises a driving motor, a belt wheel, a transmission belt, an eccentric shaft arranged on the belt wheel and a connecting rod connected on the eccentric shaft;

one end of the connecting rod is hinged on the shell of the sand and stone transporting and mixing device;

the driving motor drives the eccentric shaft to do eccentric motion through the belt wheel and the transmission belt, so as to drive the sand and stone transportation and mixing equipment which is flexibly connected with the machine frame to vibrate.

In the implementation process, the vibration equipment has a simple structure and is convenient to manufacture; meanwhile, the vibration is realized by adopting a simple transmission structure, so that the vibration-proof device is beneficial to daily maintenance, and meanwhile, consumables are easy to obtain and convenient to popularize.

Optionally, in one possible implementation:

the air supply equipment comprises an air box and a plurality of blowers, and the blowers supply air to the air box;

the air box is provided with two outlets, wherein one outlet is connected with the wind power inlet, and the other outlet is connected with the feeding hole.

In the process of realizing the device, the air supply equipment supplies air to the wind inlet and the feed inlet simultaneously, so that the device is favorable for generating a wind flow field, and can help the sand-stone mixture to smoothly enter the sand-stone transportation and mixing equipment from the feed inlet.

Optionally, in one possible implementation:

the gas supply equipment comprises a high-pressure water tank and a booster pump;

the high-pressure water tank is connected with the booster pump, and the outlet of the booster pump is communicated with the high-pressure water inlet.

Optionally, in one possible implementation:

the shell is provided with toughened glass, and the inside of the frame is provided with a refractor and light supplementing equipment;

the lateral wall of frame disposes the observation window, and the refractor refracts the inside image of toughened glass to observation window department to observe grit transportation and mixing apparatus's the inside condition.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present application and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained from the drawings without inventive effort.

FIG. 1 is a schematic view of a sand conveyor in this embodiment;

FIG. 2 is a schematic view of the sand transporting and mixing apparatus of the present embodiment;

FIG. 3 is a schematic view of the sand transporting and mixing apparatus according to the present embodiment;

FIG. 4 is a schematic view of a mixing plate according to the present embodiment;

FIG. 5 is a partial schematic view of a mixing plate according to the present embodiment;

FIG. 6 is a schematic view of a vibration device in the present embodiment;

fig. 7 is a schematic view of another mixing plate in this embodiment.

Icon: 10-a frame; 11-sand transport and mixing equipment; 12-gas supply equipment; 13-a water supply device; 14-a vibrating device; 15-a feed inlet; 16-a discharge hole; 17-wind inlet; 18-a high pressure water inlet; 19-a mixing plate; 20-a through hole; 21-a drain pipe; 22-a collision segment; 23-a connecting segment; 24-a stabilization section; 25-a drive motor; 26-a pulley; 27-a transmission belt; 28-an eccentric shaft; 29-connecting rod; 30-a gas tank; 31-blower.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application clearer, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are some embodiments of the present application, but not all embodiments. The components of the embodiments of the present application, generally described and illustrated in the figures herein, can be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present application, presented in the accompanying drawings, is not intended to limit the scope of the claimed application, but is merely representative of selected embodiments of the application. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

It should be noted that the embodiments and features of the embodiments in the present application may be combined with each other without conflict.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures.

In the description of the embodiments of the present application, it should be noted that the indication of orientation or positional relationship is based on the orientation or positional relationship shown in the drawings, or the orientation or positional relationship which is usually placed when the product of the application is used, or the orientation or positional relationship which is usually understood by those skilled in the art, or the orientation or positional relationship which is usually placed when the product of the application is used, and is only for the convenience of describing the application and simplifying the description, but does not indicate or imply that the indicated device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the application. Furthermore, the terms "first," "second," "third," and the like are used solely to distinguish one from another and are not to be construed as indicating or implying relative importance.

In the description of the embodiments of the present application, it should also be noted that, unless otherwise explicitly stated or limited, the terms "disposed," "mounted," and "connected" are to be construed broadly, and may for example be fixedly connected, detachably connected, or integrally connected; may be directly connected or indirectly connected through an intermediate. The specific meaning of the above terms in the present application can be understood in a specific case by those of ordinary skill in the art.

Example (b):

this embodiment provides a grit conveyer, and it can be at the in-process of transportation grit, promotes the quality of grit.

Referring to fig. 1 to 6, fig. 1 is a schematic view of a gravel conveyor in the present embodiment, fig. 2 is a schematic view of gravel transporting and mixing equipment in the present embodiment, fig. 3 is a schematic view of gravel transporting and mixing equipment in the present embodiment, fig. 4 is a schematic view of a mixing plate in the present embodiment, and fig. 5 is a partial schematic view of the mixing plate in the present embodiment. Fig. 6 is a schematic view of the vibration device in the present embodiment.

The sand conveyor comprises a frame 10, sand transporting and mixing equipment 11, air supply equipment 12, water supply equipment 13 and vibration equipment 14.

The sand transporting and mixing device 11 is flexibly connected with the frame 10, and the sand transporting and mixing device 11 is provided with a feeding hole 15, a discharging hole 16, a wind inlet 17 and a high-pressure water inlet 18. The air supply device 12 is arranged on the frame 10 and connected with the wind inlet 17. The water supply device 13 is arranged on the frame 10 and is connected with the high-pressure water inlet 18. The vibration device 14 is provided in the frame 10 and is connected to the sand transporting and mixing device 11 so as to vibrate it. Wherein, grit transportation and mixing apparatus 11 inside disposes mixing plate 19, and mixing plate 19 slope sets up, forms to high-end and to the low end, and feed inlet 15 is located to high-end, and discharge gate 16 is located to the low end, and wind-force import 17 and high-pressure water inlet 18 are in to high-end and to the low end between, are formed with through-hole 20 on the mixing plate 19 to make rivers and air current pass through, act on the grit.

In the implementation process, the sand-stone conveyor is used for transporting sand-stones and simultaneously mixing, colliding and rubbing the sand and the stones, so that the sizes of the sand and the stones are consistent, the quality of the sand-stones is improved, and the utilization rate of the sand-stones is improved; the sand and stone mixture is thrown to the feeding hole 15 to enter the sand and stone transporting and mixing device 11, the vibration device 14, the air supply device 12 and the water supply device 13 are started to respectively vibrate the sand and stone transporting and mixing device 11 to generate a vibration force field, high-pressure air is sprayed to the sand and stone transporting and mixing device 11 to generate a wind power flow field, high-pressure water flow is sprayed to the sand and stone transporting and mixing device 11 to generate a hydraulic flow field, the wind power flow field and the hydraulic flow field act on the sand and stone mixture through the through hole 20 formed on the mixing plate 19, the sand and the stone are impacted and rubbed with each other under the combined action of the vibration force field, the hydraulic flow field and the wind power flow field, particularly, the sand and the stone are continuously thrown to the low end from the high end under the vibration force field, meanwhile, the sand and the stone are continuously rubbed due to bumping on the mixing plate 19 to change the size of, causing it to approach sand; meanwhile, the hydraulic flow field and the wind flow field can intensify the collision violence degree of the sand and the stones, and slow down the speed of the stones and the sand flowing to the low end, so that the stones and the sand are crushed in the sand and stone transporting and mixing equipment 11 for a long time; meanwhile, the transportation and the crushing of the sand and the stones are carried out in the sand transportation and mixing device 11, and due to the existence of a hydraulic flow field, dust raising can not occur, thereby being beneficial to the environmental protection; it should be noted that the sand mixture that is eventually crushed will flow out of the outlet 16 with a portion of the water flow.

In the present disclosure, the sand transporting and mixing apparatus 11 comprises a housing, both ends of which are inclined downward and form a feed port 15 and a discharge port 16, respectively;

the wind power inlet 17 and the high-pressure water inlet 18 are arranged between the feed port 15 and the discharge port 16, and the wind power inlet 17 and the high-pressure water inlet 18 are both directed to the vertical center line of the shell;

a drain pipe 21 is disposed at the bottom of the casing.

In the implementation process, the sand-gravel mixture is discharged into the sand-gravel transporting and mixing device 11 from the lower part to the higher part, so that the speed of the sand-gravel mixture entering the sand-gravel transporting and mixing device 11 is favorably reduced, and the energy of the sand-gravel mixture passing through the sand-gravel transporting and mixing device 11 mainly comes from the common acting force of the gravity, the vibration force field, the hydraulic flow field and the wind flow field of the sand-gravel mixture, so that the sand-gravel mixture is fully acted by the vibration force field, the hydraulic flow field and the wind flow field, the purpose of uniform crushing and mixing is realized, and the utilization rate and the quality of the; meanwhile, the discharge port 16 faces downwards, so that the sandstone mixture can be discharged smoothly, and excessive crushing is avoided; simultaneously, because the grit mixture is broken and transported on mixing plate 19, so the casing can dispose the drain pipe, does benefit to the discharge of rivers, avoids a large amount of water to mix the grit and discharges to reduce the degree of difficulty of later stage screening out grit.

In the present disclosure, the mixing plate 19 includes a plurality of collision sections 22, the plurality of collision sections 22 are sequentially disposed at intervals in a direction from a high end to a low end, and the collision sections 22 are inclined downward in the direction from the high end to the low end.

In the implementation process, when the mixing plate 19 acts on the sand-gravel mixture, the vibration force field, the hydraulic flow field and the wind flow field act on the mixing plate 19, the airflow in the wind flow field and the water flow in the water flow field act on the sand and the stones through the through holes 20 of the mixing plate 19 and flow out, and the vibration force field can enable the mixing plate 19 to vibrate. The sand and the stones on the mixing plate 19 jump due to the action of the vibration power field, and under the mutual collision of the sand and the stones, the sand and the stones also move from one of the collision sections 22 to the next collision section 22, so that the sand and the stones are continuously contacted with the collision sections 22 and send collision; meanwhile, the sand with light weight which is jumped up is close to the middle part of the sand and stone transporting and mixing device 11 under the action of the air flow and the water flow which flow out from the through hole 20, a turbulent air-water mixture is formed in the middle part, and the stone on the collision section 22 is continuously rubbed under the action of the air flow and the water flow (the collision section 22 also plays a role of blocking the movement of the stone), so that the rubbing efficiency of the stone and the sand is improved, and the stone and the sand can be finally discharged from the discharge hole 16 under the action of gravity.

In the present disclosure, the mixing plate 19 further includes a connecting section 23, and two adjacent collision sections 22 are connected by the connecting section 23;

the connecting section 23 is obliquely arranged;

wherein, the included angle between the connecting section 23 and the collision section 22 is less than 90 degrees, and through holes 20 are formed between the connecting section 23 and the nozzle collision section.

In the implementation process, the collision sections 22 are smoothly connected through the connection sections 23 to ensure the structural strength of the mixing plate 19 and avoid the crushing of the mixing plate 19 caused by the action of a vibration power field, a hydraulic flow field and a wind power flow field on the mixing plate 19;

meanwhile, due to the existence of the connecting section 23, the sand-stone mixture can smoothly move from high end to low end, and the smooth transportation of sand-stone is ensured;

meanwhile, the inclined arrangement between the connection section 23 and the collision section 22 and the formation of the through holes 20 are beneficial to the guidance of air flow and water flow so as to form a turbulent air-water mixture in the middle of the sand transporting and mixing device 11.

In other embodiments, referring to fig. 7, fig. 7 is a schematic view of another mixing plate 19 in this embodiment.

The mixing plate 19 further comprises a stabilizing section 24, the stabilizing section 24 is arranged at one end of the collision section 22 facing to the high end and is connected to the connecting section 23, and the stabilizing section 24 and the connecting section 23 are perpendicular to each other.

In the above-mentioned process of realizing, the grit mixture can appear breaking away from mixing plate 19 because of the change of direction of motion after collision section 22, for guaranteeing that the grit mixture is stably on mixing plate 19, has increased stable section 24 to guarantee that the grit mixture can get back to mixing plate 19 again in the short time under its action of gravity.

In this disclosure, the mixing plate 19 is further provided with a mounting plate, the mounting plate is triangular, the inclined plane of the mounting plate is connected with the mixing plate 19, and the right-angle surface of the mounting plate is connected with the housing, so that the mixing plate 19 is stably placed in the housing.

In the implementation process, in order to ensure the inclined arrangement of the mixing plate 19 and the horizontal stability of the sand and stone transporting and mixing device 11, the triangular mounting plate is additionally arranged, and the normal transportation of a wind flow field and a hydraulic flow process to the mixing plate 19 is ensured.

In the present disclosure, the vibration device 14 includes a driving motor 25, a pulley 26, a transmission belt 27, an eccentric shaft 28 provided on the pulley 26, and a connecting rod 29 connected to the eccentric shaft 28;

one end of the connecting rod 29 is hinged to the housing of the sand transporting and mixing device 11;

the eccentric shaft 28 is driven by the drive motor 25 via the belt wheel 26 and the belt 27 to perform an eccentric motion, thereby driving the sand transporting and mixing device 11, which is flexibly connected to the frame 10, to oscillate.

In the above implementation process, the vibration device 14 has a simple structure and is convenient to manufacture; meanwhile, the vibration is realized by adopting a simple transmission structure, so that the vibration-proof device is beneficial to daily maintenance, and meanwhile, consumables are easy to obtain and convenient to popularize.

In the present disclosure, the air supply apparatus 12 includes an air tank 30 and a plurality of blowers 31, the blowers 31 supplying air to the air tank 30;

the air box 30 is formed with two outlets, one of which is connected to the wind inlet 17 and the other of which is connected to the feed port 15.

In the implementation process, the air supply device 12 supplies air to the wind power inlet 17 and the feeding hole 15 at the same time, so that the generation of a wind power flow field is facilitated, and meanwhile, the sand and stone mixture can be helped to smoothly enter the sand and stone transporting and mixing device 11 from the feeding hole 15.

In the present disclosure, the gas supply apparatus 12 includes a high-pressure water tank and a booster pump;

the high-pressure water tank is connected with a booster pump, and the outlet of the booster pump is communicated with a high-pressure water inlet 18.

In the disclosure, the shell is configured with tempered glass, and the inside of the frame 10 is configured with a refractor and a light supplement device;

the side wall of the frame 10 is provided with an observation window, and the refractor refracts the image inside the toughened glass to the observation window, so as to observe the internal condition of the sand transportation and mixing device 11.

The above description is only a preferred embodiment of the present application and is not intended to limit the present application, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application shall be included in the protection scope of the present application.

Claims

1. A sand conveyor, comprising:

a frame;

the vibrating equipment is arranged on the rack and connected with the sand and stone transporting and mixing equipment so as to vibrate;

the sand and stone transporting and mixing device is characterized in that a mixing plate is arranged inside the sand and stone transporting and mixing device, the mixing plate is obliquely arranged to form a part from high end to low end, the feeding hole is formed in the part from high end to high end, the discharging hole is formed in the part from low end to high end, the wind power inlet and the high-pressure water inlet are located between the part from high end to low end, and through holes are formed in the mixing plate so that water flow and air flow can pass through the mixing plate and act on sand and stones.

2. A sand conveyor as claimed in claim 1,

the sand and stone transporting and mixing device comprises a shell, wherein two ends of the shell are inclined downwards and respectively form the feeding hole and the discharging hole;

the wind power inlet and the high-pressure water inlet are arranged between the feed port and the discharge port, and the wind power inlet and the high-pressure water inlet are both directed to the vertical center line of the shell;

a drain pipe is disposed at the bottom of the housing.

3. A sand conveyor as claimed in claim 2,

the hybrid plate includes a plurality of collision sections, the plurality of collision sections along to high end to the direction of low end sets up at interval in proper order, the collision section along to high end to the slope down in the direction of low end.

4. A sand conveyor as claimed in claim 3,

the mixing plate further comprises connecting sections, and two adjacent collision sections are connected by the connecting sections;

the connecting section is obliquely arranged;

wherein, the linkage segment with the contained angle is less than 90 degrees between the collision section, just the linkage segment with all be formed with the through-hole between the mouth section.

5. Sand conveyor according to claim 4,

the mixing plate still includes the stable section, the stable section is located the collision section orientation to high-end one end, and connect in the linkage segment, the stable section with the linkage segment mutually perpendicular.

6. Sand conveyor according to claim 5,

the hybrid board still disposes the mounting panel, the mounting panel is triangle-shaped, the inclined plane and the hybrid board of mounting panel are connected, the right angle face and the casing of mounting panel are connected, so that the hybrid board is placed in the casing steadily.

7. A sand conveyor as in claim 6,

the vibration equipment comprises a driving motor, a belt wheel, a transmission belt, an eccentric shaft arranged on the belt wheel and a connecting rod connected to the eccentric shaft;

one end of the connecting rod is hinged to the shell of the sand and stone transporting and mixing device;

the driving motor drives the eccentric shaft to do eccentric motion through the belt wheel and the transmission belt, so as to push the sand and stone transporting and mixing equipment which is in flexible connection with the rack to vibrate.

8. A sand conveyor as in claim 7,

9. A sand conveyor as in claim 8,

10. A sand conveyor as in claim 9,

the shell is provided with toughened glass, and a refractor and light supplementing equipment are arranged inside the rack;

the lateral wall of frame disposes the observation window, the refractor will the inside image refraction of toughened glass extremely observation window department, so that observe the inside condition of grit transportation and mixing apparatus.