CN215353077U - Ceramic tile glue production equipment - Google Patents

Abstract

The utility model discloses a ceramic tile glue production device, which belongs to the technical field of ceramic tile glue production, wherein a guide plate in a half-cone structure is arranged inside the top end of a shell, the tip end of the guide plate faces downwards and is positioned inside the shell, a vertically arranged baffle is formed on the middle axial surface of the guide plate, a spiral channel for screening materials is arranged on the inner side wall of the shell, the highest end of the spiral channel and the guide plate are respectively provided with a feed inlet which is communicated with each other, the lowest end of the spiral channel and the side wall of the shell are respectively provided with a discharge outlet which is communicated with each other, the lowest end of the spiral channel is provided with a discharge mechanism for pushing large-particle materials into the discharge outlet, and the discharge mechanism is connected with a stirring mechanism through a transmission mechanism. The utility model can sieve the materials and respectively convey the sieved materials, and can also stir and mix the materials at the same time, so as to improve the treatment efficiency of the device on the raw materials for manufacturing the tile glue.

Description

Ceramic tile glue production equipment

Technical Field

The utility model relates to the technical field of ceramic tile glue production, in particular to ceramic tile glue production equipment.

Background

The tile adhesive is a modern decoration new material for sticking decoration materials such as tiles, face bricks, floor tiles and the like, and has the advantages of high cohesive force, no need of soaking bricks to wet walls in construction, good flexibility, water resistance, permeability resistance, crack resistance, good ageing resistance, high temperature resistance, freeze thawing resistance, no toxicity, environmental protection and the like by adding different types of additives in the production process.

The device of production usefulness is glued to current majority ceramic tile, before stirring each raw materials, needs sieve the raw materials that preparation ceramic tile was glued with special centrifugal device earlier, then the raw materials of rethread mixing apparatus after to the screening stirs the mixture, this with greatly reduced the treatment effeciency of device to each raw materials to the ceramic tile is glued to the device has been reduced production efficiency.

SUMMERY OF THE UTILITY MODEL

1. Technical problem to be solved

The utility model aims to provide ceramic tile glue production equipment to solve the problems in the background technology.

2. Technical scheme

In order to solve the problems, the utility model adopts the following technical scheme:

a ceramic tile adhesive production device, which comprises a shell, wherein a stirring mechanism for mixing materials is arranged inside the shell, a discharge opening is arranged on the shell, a guide plate with a half conical structure is arranged inside the top end of the shell, the tip end of the guide plate faces downwards and is positioned inside the shell, and the semicircular side surface at the top end of the guide plate is fixedly connected with the inner wall at the top end of the shell, a baffle plate which is vertically arranged is formed on the middle shaft surface of the guide plate, the inner side wall of the shell is provided with a spiral channel for sieving materials, the highest end of the spiral channel and the guide plate are respectively provided with a feed inlet which is communicated with each other, and the lowest end of the spiral channel and the side wall of the shell are respectively provided with a discharge hole which are communicated with each other, the lowest end of the spiral channel is provided with a discharging mechanism which pushes large-particle materials into the discharging port, and the discharging mechanism is connected with the stirring mechanism through a transmission mechanism.

Further, the top of casing can be dismantled and be connected with the apron, and the left side of apron not with the casing contact and form the passageway that communicates with the guide plate, stirring mechanism includes vertical axis of rotation of locating the inboard middle part of casing, equidistant stirring rod one of locating the peripheral border of axis of rotation and being located the helical coiled passage below, guide plate, apron are run through in proper order to the top of axis of rotation, and the top of axis of rotation is connected with the motor of installing on the apron through the support, all set up the perforation that supplies the axis of rotation to pass and rotate the connection with the axis of rotation on guide plate, the apron, all glue on every fenestrate inner wall and glue the sealing washer that has closely laminated with the axis of rotation lateral wall.

Furthermore, the inner bottom of the shell is provided with a collecting groove in a conical structure, the discharge port is arranged at the lowest end of the collecting groove, and the bottom end of the rotating shaft is provided with a second stirring rod parallel to the inner wall of the collecting groove.

Further, sieve mesh one has been seted up to equidistant on the arc terminal surface of guide plate, spiral channel's top is the slope setting, and the incline direction is for gradually lowering the setting to its inboard from the inner wall of casing, spiral channel's bottom equidistant set up with the inside sieve mesh two that communicate of casing.

Preferably, the discharging mechanism comprises a rotating shaft, a spiral blade and a rotating shaft, wherein the rotating shaft is horizontally arranged in the shell, one end of the rotating shaft penetrates through the side wall of the spiral channel and is positioned in the spiral channel, the spiral blade is arranged on the rotating shaft and pushes large-particle materials in the spiral channel, the horizontal central line of the rotating shaft is overlapped with the horizontal central line of the discharge port, and the rotating shaft is connected with the rotating shaft through a transmission mechanism.

Preferably, the transmission mechanism includes a driving bevel gear fixedly sleeved on the rotating shaft, and a driven bevel gear fixedly sleeved on the rotating shaft and meshed with the driving bevel gear.

Further, be equipped with on the lateral wall of helical passage and accelerate its inside material flow beat the mechanism, beat the mechanism and include through articulated seat install the articulated slab on the helical passage lateral wall, locate the hammer of beating on the articulated slab tip, the cover is equipped with the torsional spring that is used for the elastic support articulated slab on the articulated shaft on the articulated seat, beat the hammer and hug closely on the lateral wall of helical passage under the effect of torsional spring, the fixed drive rod that can drive articulated slab pivoted that is equipped with in the axis of rotation.

3. Advantageous effects

1. According to the utility model, through the flowing of the materials in the guide plate and the spiral channel, the screening effect of the device on the materials to be mixed is improved, so that the influence on the production quality of the tile glue caused by the mixing and stirring of large-particle materials is avoided, meanwhile, small-particle materials screened by the stirring mechanism in the shell can be stirred, and large-particle materials can be pushed into the discharge hole through the discharge mechanism arranged at the lower end of the spiral channel.

2. According to the utility model, the top end of the spiral channel is obliquely arranged, so that small particle materials falling to the top end of the spiral channel can flow along the oblique end face and finally enter the shell, and waste of the materials caused by accumulation of the materials on the upper end face of the spiral channel is avoided.

3. When the rotating shaft rotates, the driving rod can extrude one end, far away from the beating hammer, of the hinged plate to tilt the beating hammer from the side wall of the spiral channel, at the moment, the torsion spring on the hinged shaft is in a compressed state, and when the driving rod is separated from the hinged plate, the beating hammer can beat the side wall of the spiral channel under the action of the torsion spring, so that the flowing speed of materials in the spiral channel is accelerated, and meanwhile, the screening effect of the spiral channel on the materials is improved.

Drawings

FIG. 1 is a schematic front view of the internal structure of the present invention;

FIG. 2 is a schematic view of a portion of FIG. 1;

FIG. 3 is a schematic diagram of a top view of a baffle;

FIG. 4 is a schematic top view of the spiral channel;

fig. 5 is a schematic structural view of the tapping mechanism.

Reference numerals: 1. a housing; 2. a cover plate; 3. a baffle; 31. a baffle plate; 32. screening holes I; 4. a spiral channel; 41. a second sieve mesh; 5. a rotating shaft; 6. a helical blade; 7. a discharge port; 8. a rotating shaft; 9. a first stirring rod; 10. a discharge outlet; 11. collecting tank; 12. a stirring rod II; 13. a motor; 14. perforating; 15. a seal ring; 16. a drive bevel gear; 17. a driven bevel gear; 18. a hinged seat; 19. a hinge plate; 20. knocking a hammer; 21. a driving stick; 22. hinging a shaft; 23. a torsion spring; 24. and (4) feeding a material inlet.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and examples.

Examples

As shown in figure 1, a ceramic tile glue production device comprises a shell 1, a stirring mechanism for mixing materials is arranged inside the shell 1, a discharge hole 10 is arranged on the shell 1, a guide plate 3 with a half cone-shaped structure is arranged inside the top end of the shell 1, the tip end of the guide plate 3 faces downwards and is positioned inside the shell 1, the semicircular side surface of the top end of the guide plate 3 is fixedly connected with the inner wall of the top end of the shell 1, a baffle 31 which is vertically arranged is formed on the middle axial surface of the guide plate 3, a spiral channel 4 for sieving the materials is arranged on the inner side wall of the shell 1, the highest end of the spiral channel 4 and the guide plate 3 are respectively provided with a feed inlet 24 which is communicated with each other, the lowest end of the spiral channel 4 and the side wall of the shell 1 are respectively provided with a discharge hole 7 which is communicated with each other, the lowest end of the spiral channel 4 is provided with a discharge mechanism for pushing large-particle materials into the discharge hole 7, and the discharging mechanism is connected with the stirring mechanism through a transmission mechanism.

As shown in fig. 1 and 2, a cover plate 2 is detachably connected to the top end of a housing 1, the left side of the cover plate 2 is not in contact with the housing 1 and forms a channel communicated with a guide plate 3, a stirring mechanism comprises a rotating shaft 8 vertically arranged in the middle of the inner side of the housing 1, first stirring rods 9 arranged on the periphery of the rotating shaft 8 at equal intervals and positioned below a spiral channel 4, the guide plate 3 and the cover plate 2 sequentially penetrate through the guide plate 3 and the top end of the rotating shaft 8, a motor 13 arranged on the cover plate 2 through a bracket is connected to the top end of the rotating shaft 8, through holes 14 for the rotating shaft 8 to penetrate through and to be rotatably connected with the rotating shaft 8 are formed in the guide plate 3 and the cover plate 2, a sealing ring 15 tightly attached to the outer side wall of the rotating shaft 8 is adhered to the inner wall of each through hole 14, the rotating shaft 8 drives the first stirring rods 9 to rotate and stir and mix various materials in the housing 1 to accelerate mutual fusion between the materials, the production efficiency of the equipment for ceramic tile glue is improved.

As shown in fig. 1, the interior bottom of casing 1 is equipped with collecting vat 11 that is the toper structure, and bin outlet 10 locates the lowest end of collecting vat 11, and the bottom of axis of rotation 8 is equipped with two 12 with the parallel puddler of collecting vat 11 inner wall, the bottom is the setting of toper structure collecting vat 11 in casing 1, can carry out the water conservancy diversion to the material of casing 1 inside, in order to accelerate the device to the ejection of compact that the fashioned ceramic tile was glued, and can stir the material that lies in collecting vat 11 inboard through puddler two 12, in order to improve the device and glue the stirring effect to the ceramic tile.

As shown in fig. 2 and 3, the arc-shaped end surface of the guide plate 3 is equidistantly provided with the first sieve holes 32, the top end of the spiral channel 4 is obliquely arranged, the oblique direction is gradually lowered from the inner wall of the shell 1 to the inner side thereof, the bottom end of the spiral channel 4 is equidistantly provided with the second sieve holes 41 communicated with the inside of the shell 1, the material can be guided through the spiral channel 4, when the material flows in the spiral channel 4, the small-particle material automatically passes through the second sieve holes 41 on the bottom in the spiral channel 4 to enter the inside of the shell 1, the screened material can be stirred by the stirring mechanism in the shell 1, the large-particle material can be pushed into the discharge hole 7 by the discharging mechanism arranged at the lower end of the spiral channel 4, and the large-particle material can be conveyed to the grinding device by the related conveying device, in conclusion, the device can stir and mix the material while screening the material and conveying the screened material respectively, so as to improve the treatment efficiency of the device to the raw material for making the tile glue.

As shown in fig. 2, discharge mechanism includes that the level is located inside 1 casing and one end runs through 4 lateral walls of helical channel and is located 4 inside pivot 5 of helical channel, locate on the pivot 5 and carry out propulsive helical blade 6 to 4 inside large granule materials of helical channel, the horizontal central line of pivot 5 and the coincidence of the horizontal central line of discharge gate 7, and pivot 5 passes through drive mechanism and rotation axis 8 and is connected, the helical blade 6 that drives it when pivot 5 rotates is rotatory and will be located 4 low-end department of helical channel's large granule materials and impel, in order to accelerate the conveying efficiency of the device to the large granule material of screening out.

As shown in fig. 2, the transmission mechanism includes a driving bevel gear 16 fixedly sleeved on the rotating shaft 8, and a driven bevel gear 17 fixedly sleeved on the rotating shaft 5 and meshed with the driving bevel gear 16, and the helical blade 6 on the rotating shaft 5 can rotate along with the rotating shaft 8 by meshing the driving bevel gear 16 with the driven bevel gear 17, so that the discharging mechanism and the stirring mechanism can share one motor 13, and the manufacturing cost of the device is reduced.

As shown in fig. 4 and 5, the side wall of the spiral channel 4 is provided with a rapping mechanism for accelerating the flow of the material therein, the rapping mechanism comprises a hinged plate 19 mounted on the side wall of the spiral channel 4 through a hinged seat 18, and a rapping hammer 20 arranged on the end of the hinged plate 19, a torsional spring 23 for elastically supporting the hinged plate 19 is sleeved on a hinged shaft 22 on the hinged seat 18, the rapping hammer 20 is tightly attached to the side wall of the spiral channel 4 under the action of the torsional spring 23, a driving rod 21 for driving the hinged plate 19 to rotate is fixedly arranged on the rotating shaft 8, when the rotating shaft 8 rotates, the rapping hammer 20 is tilted from the side wall of the spiral channel 4 by the pressing of the driving rod 21 on the end of the hinged plate 19 far away from the rapping hammer 20, at this time, the torsional spring 23 on the hinged shaft 22 is in a compressed state, when the driving rod 21 is separated from the hinged plate 19, the rapping hammer 20 raps the side wall of the spiral channel 4 under the action of the torsional spring 23, therefore, the flow speed of the materials in the spiral channel 4 is accelerated, and the screening effect of the spiral channel 4 on the materials is improved.

The concrete application process of the ceramic tile adhesive production equipment comprises the following steps: when in use, the discharge port 7 on the device is connected with the feed port of the crushing pipe through the material conveying mechanism, then the discharge port of the crushing pipe is connected with the feed end of the guide plate 3 of the device through the material conveying mechanism, the specific structure of the crushing pipe is disclosed in the application No. CN 209138792U, the raw materials required for manufacturing the tile glue are conveyed to the inner part of the guide plate 3 through the material conveying mechanism, when the materials flow on the guide plate 3, the small-particle materials can pass through the first sieve mesh 32 on the guide plate 3 to enter the inner part of the shell 1, in order to improve the screening quality of the device to the materials, the materials at the lower end of the guide plate 3 can also enter the inner part of the spiral channel 4 through the feed port 24, the materials can be screened again through the spiral channel 4, namely, the small-particle materials can pass through the second sieve mesh 41 on the bottom in the period to enter the inner part of the shell 1 when flowing in the inner part of the spiral channel 4, in order to avoid the falling materials from being accumulated on the top end of the spiral channel 4, the top end of the spiral channel 4 is obliquely arranged, so that the materials falling to the top end of the spiral channel 4 can enter the shell 1 along the oblique top end surface, and the materials are prevented from being accumulated on the upper end surface of the spiral channel 4 and causing waste to the materials;

when the screened small-particle materials enter the shell 1, the rotating shaft 8 can be driven to rotate through the operation of the motor 13, so that the first stirring rod 9 on the rotating shaft 8 can stir and mix the materials in the shell 1 to accelerate the fusion between the raw materials, meanwhile, the helical blade 6 on the rotating shaft 5 can rotate along with the rotating shaft 8 through the meshing of the driving bevel gear 16 and the driven bevel gear 17, so that the helical blade 6 can push the large-particle materials at the lower end of the helical channel 4, the large-particle materials can enter the material conveying mechanism through the discharge port 7 and then enter the crushing pipe, so that the large-particle materials are screened and processed, and the crushed materials can enter the guide plate 3 through the material conveying mechanism again to realize the high-efficiency processing of the materials;

when the rotating shaft 8 rotates, the knocking hammer 20 can be tilted up from the side wall of the spiral channel 4 by squeezing one end, away from the knocking hammer 20, of the hinged plate 19 through the driving stick 21, at the moment, the torsion spring 23 on the hinged shaft 22 is in a compressed state, and when the driving stick 21 is separated from the hinged plate 19, the knocking hammer 20 can knock the side wall of the spiral channel 4 under the action of the torsion spring 23, so that the flowing speed of materials in the spiral channel 4 is accelerated, and meanwhile, the screening effect of the spiral channel 4 on the materials is improved;

after the ceramic tile glue in the casing 1 stirs the shaping, open bin outlet 10 and glue the ceramic tile and release, still can glue the ceramic tile through the collecting vat 11 that is the toper structure and carry out the water conservancy diversion simultaneously to accelerate the device to the gluey discharging efficiency of ceramic tile, and the ceramic tile glue when stirring, still can stir the material that is located collecting vat 11 inboard through puddler two 12, with the stirring effect of improvement device to the material, the use of this ceramic tile glue production facility has just so been accomplished.

It should be understood by those skilled in the art that the above embodiments are only for illustrating the present invention and are not to be used as a limitation of the present invention, and that changes and modifications to the above embodiments are within the scope of the claims of the present invention as long as they are within the spirit and scope of the present invention.

Claims (7)

1. The ceramic tile glue production equipment comprises a shell (1), wherein a stirring mechanism for mixing materials is arranged inside the shell (1), and a discharge hole (10) is formed in the shell (1), the ceramic tile glue production equipment is characterized in that a guide plate (3) with a half-cone-shaped structure is arranged inside the top end of the shell (1), the tip end of the guide plate (3) faces downwards and is positioned inside the shell (1), the semicircular side surface of the top end of the guide plate (3) is fixedly connected with the inner wall of the top end of the shell (1), a vertically arranged baffle plate (31) is formed on the middle shaft surface of the guide plate (3), a spiral channel (4) for screening the materials is arranged on the inner side wall of the shell (1), the highest end of the spiral channel (4) and the guide plate (3) are respectively provided with a feed inlet (24) which are communicated with each other, and the lowest end of the spiral channel (4) and the side wall of the shell (1) are respectively provided with a discharge hole (7) which is communicated with each other, the lowest end of the spiral channel (4) is provided with a discharging mechanism which pushes large-particle materials into the discharging port (7), and the discharging mechanism is connected with the stirring mechanism through a transmission mechanism.

2. The ceramic tile glue production equipment according to claim 1, characterized in that the top end of the shell (1) is detachably connected with a cover plate (2), the left side of the cover plate (2) is not contacted with the shell (1) and forms a channel communicated with the guide plate (3), the stirring mechanism comprises a rotating shaft (8) vertically arranged in the middle of the inner side of the shell (1), a first stirring rod (9) which is arranged on the periphery of the rotating shaft (8) at equal intervals and is positioned below the spiral channel (4), the top end of the rotating shaft (8) sequentially penetrates through the guide plate (3) and the cover plate (2), the top end of the rotating shaft (8) is connected with a motor (13) which is arranged on the cover plate (2) through a bracket, the guide plate (3) and the cover plate (2) are respectively provided with a through hole (14) for the rotating shaft (8) to pass through and be rotatably connected with the rotating shaft (8), and a sealing ring (15) tightly attached to the outer side wall of the rotating shaft (8) is adhered to the inner wall of each through hole (14).

3. The tile glue production equipment according to claim 2, characterized in that the inner bottom of the shell (1) is provided with a collecting groove (11) with a conical structure, the discharge port (10) is arranged at the lowest end of the collecting groove (11), and the bottom end of the rotating shaft (8) is provided with a stirring rod II (12) parallel to the inner wall of the collecting groove (11).

4. The tile glue production equipment according to claim 1, wherein the arc-shaped end surface of the guide plate (3) is provided with first sieve holes (32) at equal intervals, the top end of the spiral channel (4) is obliquely arranged, the oblique direction is gradually lowered from the inner wall of the shell (1) to the inner side of the shell, and the bottom end of the spiral channel (4) is provided with second sieve holes (41) at equal intervals, and the second sieve holes are communicated with the inside of the shell (1).

5. The ceramic tile glue production equipment according to claim 2, wherein the discharging mechanism comprises a rotating shaft (5) which is horizontally arranged inside the shell (1) and one end of which penetrates through the side wall of the spiral channel (4) and is positioned inside the spiral channel (4), and a spiral blade (6) which is arranged on the rotating shaft (5) and pushes large-particle materials inside the spiral channel (4), the horizontal center line of the rotating shaft (5) is overlapped with the horizontal center line of the discharging port (7), and the rotating shaft (5) is connected with the rotating shaft (8) through a transmission mechanism.

6. A tile glue production plant according to claim 5, characterized in that said transmission means comprise a driving conical gear (16) fixed to said rotation shaft (8), and a driven conical gear (17) fixed to said rotation shaft (5) and engaged with said driving conical gear (16).

7. The ceramic tile glue production equipment according to claim 2, wherein a beating mechanism for accelerating flowing of materials inside the spiral channel (4) is arranged on the side wall of the spiral channel, the beating mechanism comprises a hinged plate (19) installed on the side wall of the spiral channel (4) through a hinged seat (18), and a beating hammer (20) arranged on the end portion of the hinged plate (19), a torsion spring (23) for elastically supporting the hinged plate (19) is sleeved on a hinged shaft (22) on the hinged seat (18), the beating hammer (20) is tightly attached to the side wall of the spiral channel (4) under the action of the torsion spring (23), and a driving rod (21) capable of driving the hinged plate (19) to rotate is fixedly arranged on the rotating shaft (8).

Images