CN220640296U - Quantitative split charging device for dry powder mortar processing - Google Patents

Abstract

The utility model discloses a quantitative split charging device for dry powder mortar processing, which comprises four groups of supporting legs, device frames, storage barrels and stirring components, wherein the top ends of the four groups of supporting legs are provided with the device frames, the storage barrels are arranged in the device frames, and the stirring components are arranged on the storage barrels; the stirring assembly comprises a driving motor, a transmission rod, a connecting column and a scraping plate, and the driving motor is installed on one side of the device frame. According to the utility model, the stirring assembly is arranged, the transmission rod rotates, the connecting column and the scraping plate rotate together, dry powder mortar is stirred in the storage barrel, the scraping plate is attached to the inner wall of the storage barrel, the dry powder mortar can be prevented from adhering to the inner wall of the storage barrel, meanwhile, the dry powder mortar is kept loose in the storage barrel, caking is prevented, discharging is prevented, the transmission rod rotates along with the connecting rod through the belt pulley, and the connecting disc rotates along with the connecting rod, so that the dry powder mortar in the groove of the connecting disc is discharged.

Description

Quantitative split charging device for dry powder mortar processing

Technical Field

The utility model relates to the technical field of dry powder mortar split charging, in particular to a quantitative split charging device for dry powder mortar processing.

Background

The dry powder mortar is a granular or powdery material which is formed by physically mixing aggregate (such as quartz sand) subjected to drying and screening treatment, inorganic cementing material (such as cement) and additive (such as polymer) according to a certain proportion, is transported to a construction site in a bag or bulk mode, and can be directly used after being mixed with water. Also known as mortar dry powder, dry-mixed mortar, dry-mixed powder, and some building adhesives are of this type. The dry powder mortar plays roles of bonding, lining, protection and decoration in a thin layer in the construction industry, and has extremely wide application in construction and decoration engineering.

The dry powder mortar is packaged by the packaging device, and is easy to agglomerate in the device when stored in the packaging device, or moves on the inner wall, and the agglomeration of the dry powder mortar in the device can affect the discharge, so that the quantitative packaging device for dry powder mortar processing is provided.

Disclosure of Invention

The utility model aims to solve the defects in the prior art, and provides a quantitative split charging device for processing dry powder mortar.

In order to achieve the above purpose, the present utility model adopts the following technical scheme:

the quantitative split charging device for processing the dry powder mortar comprises four groups of supporting legs, device frames, storage barrels and stirring components, wherein the device frames are arranged at the top ends of the four groups of supporting legs, the storage barrels are arranged in the device frames, and the stirring components are arranged on the storage barrels;

the stirring assembly comprises a driving motor, a transmission rod, connecting columns and scraping plates, wherein the driving motor is installed on one side of the device frame, the transmission rod is connected with the inside of the storage barrel in a rotating mode, six groups of connecting columns are symmetrically installed on the transmission rod, and the scraping plates are installed at one ends of the connecting columns.

Further, one end of the transmission rod penetrates through one end of the storage barrel to extend outwards, one end of the transmission rod is fixedly connected with the power output end of the driving motor, the top end of the device frame is provided with a feed hopper, and the bottom of the feed hopper penetrates through the device frame and is connected with the storage barrel.

Further, the backup pad is installed to the bottom of supporting leg, be provided with the transfer table in the backup pad, the play storage vat is installed to the bottom symmetry of device frame, two sets of the top of play storage vat runs through the device frame and is linked together with the storage vat.

Further, the other end of transfer line runs through storage vat and device frame to outside extension, and the belt pulley is installed to the other end of transfer line, the fixed plate is installed to the bottom symmetry of device frame, it is connected with the connecting rod to rotate on the fixed plate, the connecting rod runs through two sets of play storage vats, the connection pad is installed to the symmetry on the connecting rod.

Further, two groups of connecting discs are respectively located inside two groups of discharging barrels, two groups of the discharging barrels are respectively provided with a baffle plate, the middle position of each baffle plate is provided with a leak hole, grooves are symmetrically formed in the connecting discs, and arc-shaped grooves matched with the connecting discs are formed in the bottoms of the baffle plates.

Further, suction fans are symmetrically arranged on the back sides of the supporting legs, connecting cylinders are arranged at the suction ends of the two groups of suction fans, the two groups of connecting cylinders correspond to the bottom of the discharge barrel, and collecting cylinders are arranged on the connecting cylinders.

The beneficial effects of the utility model are as follows:

through the stirring subassembly that sets up, the transfer line rotates, spliced pole and scraper blade rotate together, stirs dry powder mortar in the inside of storage vat, and the scraper blade is laminated with the inner wall of storage vat, can prevent that dry powder mortar from depending on at the inner wall of storage vat, keeps dry powder mortar to be loose form in the inside of storage vat simultaneously, prevents the caking, influences the discharge, drives the connecting rod through the belt pulley when the transfer line rotates and rotates together, and the connection pad rotates along with the connecting rod, and dry powder mortar in the connection pad recess discharges.

Drawings

Fig. 1 is a schematic diagram of the overall structure of a quantitative split charging device for dry powder mortar processing;

fig. 2 is a side view of the whole structure of the quantitative subpackaging device for processing dry powder mortar;

fig. 3 is a side view of a connection structure of a suction fan and a connecting cylinder of the quantitative split charging device for processing dry powder mortar;

fig. 4 is a schematic diagram of the internal structure of a device frame of a quantitative subpackaging device for dry powder mortar processing;

fig. 5 is a top view of the internal structure of a storage vat of the quantitative split charging device for processing dry powder mortar;

fig. 6 is a schematic diagram of the internal structure of a discharge barrel of the quantitative subpackaging device for processing dry powder mortar;

fig. 7 is a cross-sectional view of a partition plate structure of a quantitative split charging device for dry powder mortar processing.

In the figure: 1. a support plate; 2. a transfer station; 3. support legs; 4. a device frame; 5. a feed hopper; 6. a driving motor; 7. discharging barrels; 8. a fixing plate; 9. a belt pulley; 10. a connecting rod; 11. a suction fan; 12. a connecting cylinder; 13. a collection cylinder; 14. a storage barrel; 15. a transmission rod; 16. a connecting column; 17. a scraper; 18. a connecting disc; 19. a partition board.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments.

Referring to fig. 1 and 4, a quantitative split charging device for dry powder mortar processing comprises supporting legs 3, a device frame 4, a storage barrel 14 and a stirring assembly, wherein the supporting legs 3 are provided with four groups in total, the top ends of the supporting legs 3 are provided with the device frame 4, the storage barrel 14 is installed in the device frame 4, and the stirring assembly is arranged on the storage barrel 14.

Referring to fig. 5, the stirring assembly comprises a driving motor 6, a transmission rod 15, a connecting column 16 and a scraping plate 17, wherein the driving motor 6 is installed on one side of the device frame 4, the transmission rod 15 is connected with the inside of the storage vat 14 in a rotating manner, six groups of connecting columns 16 are symmetrically installed on the transmission rod 15, the scraping plate 17 is installed at one end of the connecting column 16, the scraping plate 17 is attached to the inside of the storage vat 14, the driving motor 6 drives the transmission rod 15 to rotate, the scraping plate 17 rotates in the inside of the storage vat 14, dry powder mortar in the storage vat 14 is stirred, the dry powder mortar is prevented from caking in the inside of the storage vat 14, and split charging is not easy.

Referring to fig. 1 and 2, one end of the transmission rod 15 extends to the outside through one end of the storage vat 14, one end of the transmission rod 15 is fixedly connected with the power output end of the driving motor 6, the top end of the device frame 4 is provided with a feed hopper 5, the bottom of the feed hopper 5 penetrates through the device frame 4 and is connected with the storage vat 14, the bottom of the supporting leg 3 is provided with a supporting plate 1, and the supporting plate 1 is provided with a conveying table 2;

the device comprises a device frame 4, a storage vat 7, a driving rod 15, a belt pulley 9, a connecting rod 10, a fixing plate 8, a connecting rod 10 and two groups of discharging barrels 7, wherein the bottom of the device frame 4 is symmetrically provided with the discharging barrels 7, the top ends of the two groups of discharging barrels 7 penetrate through the device frame 4 and are communicated with the storage vat 14, the other ends of the driving rod 15 penetrate through the storage vat 14 and the device frame 4 to extend outwards, the belt pulley 9 is arranged at the other end of the driving rod 15, one end of the belt pulley 9 is connected with the connecting rod 10, the connecting rod 10 is driven to rotate through the belt pulley 9 when the driving rod 15 rotates, the fixing plate 8 is symmetrically provided with the bottom of the device frame 4, the connecting rod 10 is connected to the fixing plate 8 in a rotating mode, and the connecting rod 10 penetrates through the two groups of discharging barrels 7.

Referring to fig. 6 and 7, the connecting rod 10 is symmetrically provided with the connecting disc 18, when the connecting rod 10 rotates, the connecting disc 18 rotates in the discharging barrel 7, two groups of connecting discs 18 are respectively positioned in the two groups of discharging barrels 7, the two groups of discharging barrels 7 are internally provided with the baffle 19, the middle position of the baffle 19 is provided with a leak hole, the connecting disc 18 is symmetrically provided with a groove, dry powder mortar in the storage barrel 14 flows into the groove on the connecting disc 18 through the leak hole on the baffle 19, when the connecting disc 18 rotates, dry powder mortar in the groove is discharged through the discharging barrel 7, the discharging amount is the same each time, and the bottom of the baffle 19 is provided with an arc-shaped groove matched with the connecting disc 18.

Referring to fig. 2 and 3, suction fans 11 are symmetrically installed on the back of the supporting leg 3, connecting barrels 12 are installed at suction ends of the two groups of suction fans 11, the two groups of connecting barrels 12 correspond to the bottom of the discharging barrel 7, a collecting barrel 13 is arranged on the connecting barrel 12, the suction fans 11 operate to suck flying dust of dry powder mortar discharged through the discharging barrel 7, the flying dust is reduced, the collecting barrel 13 is used for collecting the sucked dust, and the collecting barrel 13 is in threaded connection with the connecting barrel 12 to facilitate removal and cleaning.

Working principle: during the use, pour into dry powder mortar through feeder hopper 5, dry powder mortar deposits in storage vat 14, place the sack of dress mortar in the below of two sets of ejection of compact barrels 7 respectively, driving motor 6 operation drives transfer line 15 and rotates, spliced pole 16 and scraper blade 17 rotate in storage vat 14 inside, the inner wall laminating of scraper blade 17 and storage vat 14 stirs dry powder mortar in storage vat 14, dry powder mortar falls into in ejection of compact barrel 7, the leak hole through baffle 19 falls into the recess on connection pad 18, drive connecting rod 10 rotation through belt pulley 9 when transfer line 15 is rotatory, drive connection pad 18 rotation when connecting rod 10 rotates, dry powder mortar in the connection pad 18 recess pours out and falls into the sack and carries out the partial shipment, when dry powder mortar discharges through ejection of compact barrel 7, suction fan 11 is the operation form, inhale the dust of flying.

The foregoing is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art, who is within the scope of the present utility model, should make equivalent substitutions or modifications according to the technical scheme of the present utility model and the inventive concept thereof, and should be covered by the scope of the present utility model.

In the description of this patent, it should be understood that the terms "center," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, merely to facilitate describing the patent and simplify the description, and do not indicate or imply that the devices or elements being referred to must have a particular orientation, be configured and operated in a particular orientation, and are therefore not to be construed as limiting the patent.

Claims (6)

1. The quantitative split charging device for processing the dry powder mortar is characterized by comprising four groups of supporting legs (3), device frames (4), storage barrels (14) and stirring components, wherein the four groups of supporting legs (3) are provided with the device frames (4) at the top ends of the four groups of supporting legs (3), the storage barrels (14) are arranged in the device frames (4), and the stirring components are arranged on the storage barrels (14);

the stirring assembly comprises a driving motor (6), a transmission rod (15), connecting columns (16) and scraping plates (17), wherein the driving motor (6) is installed on one side of the device frame (4), the transmission rod (15) is connected with the inside of the storage barrel (14) in a rotating mode, six groups of connecting columns (16) are symmetrically installed on the transmission rod (15), and the scraping plates (17) are installed at one ends of the connecting columns (16).

2. The quantitative split charging device for dry powder mortar processing according to claim 1, wherein one end of the transmission rod (15) penetrates through one end of the storage vat (14) to extend outwards, one end of the transmission rod (15) is fixedly connected with a power output end of the driving motor (6), a feed hopper (5) is mounted at the top end of the device frame (4), and the bottom of the feed hopper (5) penetrates through the device frame (4) to be connected with the storage vat (14).

3. The quantitative split charging device for dry powder mortar processing according to claim 1, wherein the bottom of the supporting leg (3) is provided with a supporting plate (1), the supporting plate (1) is provided with a conveying table (2), the bottom of the device frame (4) is symmetrically provided with a discharging barrel (7), and the top ends of the two groups of discharging barrels (7) penetrate through the device frame (4) and are communicated with a storage barrel (14).

4. The quantitative split charging device for dry powder mortar processing according to claim 1, wherein the other end of the transmission rod (15) penetrates through the storage vat (14) and the device frame (4) to extend outwards, the other end of the transmission rod (15) is provided with the belt pulley (9), the bottom of the device frame (4) is symmetrically provided with the fixing plate (8), the fixing plate (8) is rotationally connected with the connecting rod (10), the connecting rod (10) penetrates through the two groups of discharging barrels (7), and the connecting disc (18) is symmetrically arranged on the connecting rod (10).

5. The quantitative split charging device for dry powder mortar processing according to claim 4, wherein two groups of connecting discs (18) are respectively positioned in two groups of discharging barrels (7), partition plates (19) are respectively arranged in the two groups of discharging barrels (7), leakage holes are formed in the middle positions of the partition plates (19), grooves are symmetrically formed in the connecting discs (18), and arc-shaped grooves matched with the connecting discs (18) are formed in the bottoms of the partition plates (19).

6. The quantitative split charging device for dry powder mortar processing according to claim 1, wherein suction fans (11) are symmetrically arranged on the back surfaces of the supporting legs (3), connecting cylinders (12) are arranged at the suction ends of the two groups of suction fans (11), the two groups of connecting cylinders (12) correspond to the bottoms of the discharging cylinders (7), and collecting cylinders (13) are arranged on the connecting cylinders (12).