CN112169620A

CN112169620A - Synchronous discharging equipment of multiple raw materials ration for haydite production

Info

Publication number: CN112169620A
Application number: CN202010940101.2A
Authority: CN
Inventors: 陈文均
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-09-09
Filing date: 2020-09-09
Publication date: 2021-01-05

Abstract

The invention relates to a discharging device, in particular to a quantitative and synchronous discharging device for multiple raw materials for ceramsite production. The technical problem is to provide the quantitative and synchronous discharging equipment for the multiple raw materials for producing the ceramsite, which can mix the raw materials in the same amount and stir the raw materials without consuming too much manpower. The utility model provides a haydite production is with synchronous discharging equipment of multiple raw materials ration, including: the supporting seat is characterized in that a speed reduction motor is installed on one side of the top of the supporting seat; the material mixing frame is connected between the tops of the supporting seats through bolts. The invention can mix the same amount of raw materials together and stir the raw materials simultaneously without consuming too much manpower, and people only need to place a plurality of different raw materials between the separating plates in the blanking frame and then adjust the distance between the baffle and the groove in the conveying roller, thus the blanking amount can be controlled.

Description

Synchronous discharging equipment of multiple raw materials ration for haydite production

Technical Field

The invention relates to a discharging device, in particular to a quantitative and synchronous discharging device for multiple raw materials for ceramsite production.

Background

The ceramsite is ceramic particles, the appearance characteristics of the ceramsite are generally round or oval spheres, and some imitation macadam ceramsite are irregular macadam-shaped, so that the raw materials for producing the ceramsite are many, and different pigments need to be quantitatively mixed together, so that the color is also many.

In the prior art, people usually mix a plurality of raw materials together quantitatively and then fully stir the raw materials to uniformly mix the raw materials, and the colors of the finally obtained materials are consistent due to the fact that the raw materials are quantitative.

Therefore, it is necessary to design a quantitative and synchronous discharging device for multiple raw materials for ceramsite production, which can mix and stir the same amount of raw materials simultaneously and does not consume too much manpower for overcoming the disadvantages of the prior art.

Disclosure of Invention

In order to overcome the shortcoming that the prior art is difficult to mix a plurality of different raw materials together quantitatively and needs to consume too much manpower, the technical problem is as follows: the utility model provides a can be with the raw materials of equivalent quantity mix simultaneously together to stir it, and need not consume the synchronous discharging equipment of multiple raw materials ration for the haydite production of too much manpower.

The technical scheme is as follows: the utility model provides a haydite production is with synchronous discharging equipment of multiple raw materials ration, including: the supporting seat is characterized in that a speed reduction motor is installed on one side of the top of the supporting seat; the material mixing frame is connected between the tops of the supporting seats through bolts; the blanking frame is connected to the top of the material combining frame; the blanking assembly is arranged in the blanking frame; and the mixing assembly is arranged at the lower part of the material mixing frame.

Optionally, the unloading subassembly includes: the separation plates are uniformly connected among the blanking frames at intervals, and the number of the separation plates is at least four; the conveying roller is rotatably arranged at the lower part of the blanking frame, and grooves are uniformly spaced on the conveying roller; and the transmission device is connected between the conveying roller and an output shaft of the speed reducing motor.

Optionally, the mixing assembly comprises: the first rotating plate is rotatably arranged at the lower part of the material combining frame; a first gear welded to one end of the first rotor plate; the arc plates are symmetrically and fixedly connected to the lower part of the material combining frame, and the upper parts of the arc plates are in contact with the first rotating plate; the striker plate is rotatably arranged at the lower part of the material combining frame and is in contact with the arc-shaped plates at two sides; the first guide rail is arranged at the lower part of the supporting seat close to one side of the first gear, and the first guide rail is also arranged at the lower part of the material combining frame; the second guide rail is arranged between the first guide rails in a sliding manner; the first connecting rod is arranged on the second guide rail in a sliding and rotating mode and is fixedly connected with an output shaft of the speed reducing motor; the second connecting rod is connected to the second guide rail; the L-shaped rack is connected to one end of the second connecting rod; the third guide rail is installed at the lower part of the material mixing frame and is connected with the L-shaped rack in a sliding manner; the second rotating plate is fixedly connected to the material baffle plate and is in fit contact with the L-shaped rack; and the torsion spring is connected between the second rotating plate and the material combining frame.

Optionally, still include the limit material subassembly, limit material subassembly including: the first guide sleeve is arranged on one side of the top of the material mixing frame; the baffle plates are arranged in the first guide sleeve at regular intervals in a sliding manner, the number of the baffle plates is at least four, and the baffle plates are respectively positioned in the grooves on the conveying roller; a fourth guide rail mounted on the first guide sleeve; the third connecting rod is arranged on the fourth guide rail in a sliding manner; the pull rod is connected to the third connecting rod; the first spring is connected between the third connecting rod and the first guide sleeve and sleeved on the fourth guide rail; the bottom of each baffle is fixedly connected with the push rod, and the push rods are connected with the first guide sleeves in a sliding mode; the second spring is connected between the first guide sleeve and the push rod; the first racks are welded on one sides of the baffles; the second guide sleeves are uniformly arranged on the first guide sleeves at intervals; the sliding rods are arranged in the second guide sleeves in a sliding mode and are in matched contact with the third connecting rod; the third spring is connected between the sliding rod and the second guide sleeve; the first rack is meshed with the first gear, and the one-way gear is arranged at one end of the sliding rod in an equal rotating mode.

Optionally, the method further includes: the limiting rod is connected to one end of the L-shaped rack; the square block is connected to the first rotating plate and is in fit contact with the limiting rod.

The beneficial effects are that: the invention can mix and stir the same amount of raw materials simultaneously, and does not need to consume too much manpower, people only need to place a plurality of different raw materials between the separating plates in the blanking frame, and then adjust the distance between the baffle and the groove in the conveying roller, so that the blanking amount can be controlled, the plurality of raw materials in the blanking frame can fall into the material mixing frame, and then the raw materials are stirred by the continuous rotation of the first rotating plate.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic sectional structural view of the blanking assembly of the present invention.

Fig. 3 is a schematic perspective view of the hybrid module of the present invention.

Fig. 4 is a schematic perspective view of the hybrid module, the limiting rod and the square block of the present invention.

Fig. 5 is a schematic perspective view of the material limiting assembly of the present invention.

Fig. 6 is a schematic perspective view of a portion of the material limiting assembly of the present invention.

Description of reference numerals: 1_ supporting seat, 2_ speed reducing motor, 3_ blanking frame, 4_ material combining frame, 5_ blanking assembly, 51_ separating plate, 52_ conveying roller, 53_ groove, 54_ transmission device, 6_ mixing assembly, 62_ first rotating plate, 63_ first gear, 64_ arc plate, 65_ material baffle plate, 66_ first guide rail, 67_ second guide rail, 68_ first connecting rod, 69_ second connecting rod, 610_ third guide rail, 611_ L-shaped rack, 612_ second rotating plate, 613_ torsion spring, 7_ material limiting assembly, 71_ first guide sleeve, 72_ baffle plate, 73_ third connecting rod, 74_ pull rod, 75_ fourth guide rail, 76_ first spring, 77_ push rod, 78_ second spring, 79_ first rack, 710_ second guide sleeve, 711_ third spring, 712_ slide rod, 713_ one-way gear, 8_ limit rod, 9_ square block.

Detailed Description

The preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Example 1

A multi-raw-material quantitative synchronous discharging device for ceramsite production is shown in figures 1-4 and comprises a supporting seat 1, a speed reduction motor 2, a discharging frame 3, a material combining frame 4, a discharging assembly 5 and a mixing assembly 6, wherein the speed reduction motor 2 is installed on the right side of the top of the supporting seat 1, the top of the supporting seat 1 is connected with the material combining frame 4 through bolts, the top of the material combining frame 4 is connected with the discharging frame 3, the discharging assembly 5 is arranged in the discharging frame 3, and the mixing assembly 6 is arranged on the lower portion of the material combining frame 4.

The blanking assembly 5 comprises separating plates 51, conveying rollers 52 and a transmission device 54, a plurality of separating plates 51 are uniformly connected between the blanking frames 3 at intervals, the conveying rollers 52 are rotatably arranged on the lower portions of the blanking frames 3, grooves 53 are uniformly formed in the conveying rollers 52 at intervals, and the transmission device 54 is connected between the right sides of the conveying rollers 52 and an output shaft of the speed reducing motor 2.

The mixing component 6 comprises a first rotating plate 62, a first gear 63, an arc-shaped plate 64, a material baffle plate 65, a first guide rail 66, a second guide rail 67, a first connecting rod 68, a second connecting rod 69, a third guide rail 610, an L-shaped rack 611, a second rotating plate 612 and a torsion spring 613, wherein the first rotating plate 62 is rotatably arranged at the lower part of the material combining frame 4, the first gear 63 is welded at the right end of the first rotating plate 62, the arc-shaped plates 64 are symmetrically and fixedly connected with the lower part of the material combining frame 4 in a front-back manner, the upper part of the arc-shaped plate 64 is contacted with the first rotating plate 62, the material baffle plate 65 is rotatably arranged at the lower part of the material combining frame 4, the material baffle plate 65 is contacted with the arc-shaped plates 64 at the front side and the rear side, the first guide rail 66 is arranged at the lower part of the right side of the support seat 1, the first guide rail 66 is also arranged at the right side of the lower part of the material combining frame 4, the second, the left part of the second guide rail 67 is connected with a second connecting rod 69, the left end of the second connecting rod 69 is connected with an L-shaped rack 611, the right side of the lower part of the material combining frame 4 is provided with a third guide rail 610, the third guide rail 610 is connected with the L-shaped rack 611 in a sliding manner, the right part of the material baffle plate 65 is fixedly connected with a second rotating plate 612, the second rotating plate 612 is in matched contact with the L-shaped rack 611, and a torsion spring 613 is connected between the second rotating plate 612 and the material combining frame 4.

When people need mix multiple raw materials and carry out the synchronous ejection of compact of ration, can use this equipment, at first place multiple different raw materials respectively in unloading subassembly 5, then start gear motor 2, thereby drive unloading subassembly 5 function, with multiple raw materials quantitative transportation to in the material frame 4 that closes, mixing assembly 6 can stir the raw materials simultaneously and mix, then make the raw materials of mixing drop, people need constantly to place the collection frame in closing material frame 4 below, the mixed raw materials that will drop are collected, when people do not need the ejection of compact, close gear motor 2 can.

When people need carry out the unloading through unloading subassembly 5, people at first put the raw materials of different colours respectively between the separator plate 51 of unloading frame 3, gear motor 2's output shaft can drive transfer roller 52 continuous anticlockwise rotation through transmission 54, and drive the raw materials and constantly rotate, because the recess 53 contact on unloading frame 3 rear portion and the transfer roller 52, make the raw materials can not drop from unloading frame 3 rear portion, so the raw materials in the unloading frame 3 can be followed the unloading frame 3 front side and dropped to in the material frame 4 that closes.

When people need to mix and output the raw materials through the mixing component 6, the raw materials drop from the blanking frame 3 onto the first rotating plate 62, the speed reduction motor 2 drives the first connecting rod 68 to rotate anticlockwise continuously, the first connecting rod 68 slides up and down in the second guide rail 67, so the second guide rail 67 moves back and forth on the first guide rail 66 continuously, and further drives the second connecting rod 69 and the L-shaped rack 611 to move back and forth continuously, because the L-shaped rack 611 is meshed with the first gear 63, the L-shaped rack 611 moves back and forth to make the first gear 63 rotate continuously, so as to drive the first rotating plate 62 to rotate continuously, and further mix and stir a plurality of raw materials on the first rotating plate 62, the teeth of the L-shaped rack 611 are long, so after the first gear 63 rotates for several circles, the raw materials are sufficiently stirred, the L-shaped rack 611 moves backwards to be separated from the first gear 63, and then the second rotating plate 612 is pushed, so that the second rotating plate 612 and the striker plate 65 rotate 90 degrees, the torsion spring 613 deforms, the raw material can automatically drop, when the L-shaped rack 611 moves forward to be separated from the second rotating plate 612, the second rotating plate 612 and the striker plate 65 automatically reset under the action of the torsion spring 613, and the reciprocating operation can make the raw material drop after being sufficiently stirred.

Example 2

On the basis of embodiment 1, as shown in fig. 4-6, the material limiting device 7 further includes a material limiting assembly 7, the material limiting assembly 7 includes a first guide sleeve 71, a baffle 72, a third connecting rod 73, a pull rod 74, a fourth guide rail 75, a first spring 76, a push rod 77, a second spring 78, a first rack 79, a second guide sleeve 710, a third spring 711, a slide rod 712 and a one-way gear 713, the first guide sleeve 71 is installed on the front side of the top of the material combining frame 4, a plurality of baffles 72 are evenly and slidably installed in the first guide sleeve 71, the baffles 72 are respectively located in the grooves 53 on the conveying rollers 52, the fourth guide rail 75 is installed on the front portion of the first guide sleeve 71, the third connecting rod 73 is slidably installed on the fourth guide rail 75, the pull rod 74 is connected to the upper side of the right portion of the third connecting rod 73, the first spring 76 is connected between the third connecting rod 73 and the first guide sleeve 71, the first spring 76 is sleeved on the fourth guide rail 75, the push rod 77 is connected with the first guide sleeve 71 in a sliding mode, the second spring 78 is connected between the first guide sleeve 71 and the push rod 77, the first rack 79 is welded on the right portion of the baffle 72, the plurality of second guide sleeves 710 are evenly installed on the first guide sleeve 71 at intervals, the sliding rods 712 are arranged in the second guide sleeves 710 in a sliding mode, the sliding rods 712 are in matched contact with the third connecting rods 73, the third springs 711 are connected between the sliding rods 712 and the second guide sleeves 710, the front ends of the sliding rods 712 are provided with one-way gears 713 in a rotating mode, and the one-way gears 713 are meshed with the first rack 79.

Still include gag lever post 8 and square piece 9, L shape rack 611 front end is connected with gag lever post 8, and first commentaries on classics board 62 right part is connected with square piece 9, and square piece 9 and gag lever post 8 cooperation contact.

One can adjust the distance between the baffle 72 and the groove 53 in the conveying roller 52, so as to control the blanking amount, in the initial state, the baffle 72 contacts with the groove 53, when one needs blanking, one pulls the baffle 72 forward to a proper position, so as to drive the first rack 79 and the push rod 77 to move forward, the second spring 78 is stretched, and the one-way gear 713 rotates, when the baffle 72 stops moving, the first rack 79 is blocked under the action of the one-way gear 713, the baffle 72 cannot move to the rear side, when one does not need blanking, the pull rod 74 is pulled to the right side, so as to drive the third link 73 to move to the right, the first spring 76 is compressed, so as to drive the one-way gear 713 and the slide rod 712 to move to the right, the third spring 711 is compressed, the one-way gear 713 does not block the first rack 79 any more, under the reset action of the second spring 78, the push rod 77, the baffle 72 and the first rack 79 reset backwards, the shutter 72 will again contact the groove 53 of the transfer roller 52 and stop the material, releasing the pull rod 74, the pull rod 74 and the third link 73 will be reset by the first spring 76, and the slide 712 and the one-way gear 713 will be reset by the third spring 711.

When the L-shaped rack 611 moves backward to be separated from the first gear 63, the limiting rod 8 is just in contact with the square block 9 and blocks the square block 9, so that the first rotating plate 62 cannot rotate, the raw material in the blanking frame 3 cannot fall off when the second rotating plate 612 is opened, when the L-shaped rack 611 moves forward, the limiting rod 8 is separated from the square block 9, and the first rotating plate 62 can continue to rotate.

While the disclosure has been shown and described with reference to certain exemplary embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the disclosure as defined by the appended claims and their equivalents. Accordingly, the scope of the present disclosure should not be limited to the above-described embodiments, but should be defined not only by the appended claims, but also by equivalents thereof.

Claims

1. The utility model provides a haydite production is with synchronous discharging equipment of multiple raw materials ration which characterized in that, including:

the device comprises a supporting seat (1), wherein a speed reducing motor (2) is installed on one side of the top of the supporting seat (1);

the material mixing frame (4) is connected between the tops of the supporting seats (1) through bolts;

the blanking frame (3) is connected to the top of the material mixing frame (4);

the blanking assembly (5), the blanking assembly (5) is arranged in the blanking frame (3);

the mixing component (6), the mixing component (6) is arranged at the lower part of the material mixing frame (4).

2. The device for quantitatively and synchronously discharging a plurality of raw materials for producing ceramsite according to claim 1, wherein the discharging component (5) comprises:

the separating plates (51), the separating plates (51) are connected between the blanking frames (3) at regular intervals, and the number of the separating plates (51) is at least four;

the conveying roller (52) is rotatably arranged at the lower part of the blanking frame (3), and grooves (53) are uniformly spaced on the conveying roller (52);

a transmission device (54), wherein the transmission device (54) is connected between the conveying roller (52) and an output shaft of the speed reducing motor (2).

3. The equipment for quantitatively and synchronously discharging a plurality of raw materials for producing ceramsite according to claim 2, wherein the mixing component (6) comprises:

the first rotating plate (62), the first rotating plate (62) is rotatably arranged at the lower part of the material combining frame (4);

a first gear (63), the first gear (63) being welded to one end of the first rotating plate (62);

the arc-shaped plates (64) are symmetrically and fixedly connected to the lower part of the material mixing frame (4), and the upper parts of the arc-shaped plates (64) are in contact with the first rotating plate (62);

the material blocking plate (65) is rotatably arranged at the lower part of the material combining frame (4), and the material blocking plate (65) is in contact with the arc-shaped plates (64) at two sides;

the first guide rail (66), the first guide rail (66) is installed at the lower part of the supporting seat (1) close to one side of the first gear (63), and the first guide rail (66) is also installed at the lower part of the material combining frame (4);

a second guide rail (67), the second guide rail (67) being slidably disposed between the first guide rails (66);

the first connecting rod (68) is arranged on the second guide rail (67) in a sliding mode and in a rotating mode, and the first connecting rod (68) is fixedly connected with an output shaft of the speed reducing motor (2);

a second link (69), the second link (69) being connected to the second rail (67);

an L-shaped rack (611), wherein the L-shaped rack (611) is connected to one end of the second connecting rod (69);

the third guide rail (610) is mounted at the lower part of the material mixing frame (4), and the third guide rail (610) is connected with the L-shaped rack (611) in a sliding manner;

the second rotating plate (612) is fixedly connected to the striker plate (65), and the second rotating plate (612) is in fit contact with the L-shaped rack (611);

a torsion spring (613), the torsion spring (613) being connected between the second rotating plate (612) and the alloy frame (4).

4. The multi-raw-material quantitative synchronous discharging equipment for ceramsite production according to claim 3, further comprising a material limiting component (7), wherein the material limiting component (7) comprises:

the first guide sleeve (71), the first guide sleeve (71) is arranged on one side of the top of the material mixing frame (4);

the baffles (72) are arranged in the first guide sleeve (71) in a sliding manner at uniform intervals, the number of the baffles (72) is at least four, and the baffles (72) are respectively positioned in the grooves (53) on the conveying roller (52);

a fourth guide rail (75), the fourth guide rail (75) being mounted on the first guide sleeve (71);

a third link (73), the third link (73) being slidably disposed on the fourth rail (75);

a pull rod (74), wherein the pull rod (74) is connected to the third connecting rod (73);

a first spring (76), wherein the first spring (76) is connected between the third connecting rod (73) and the first guide sleeve (71), and the first spring (76) is sleeved on the fourth guide rail (75);

the bottom of each baffle (72) is fixedly connected with the corresponding push rod (77), and the push rods (77) are connected with the first guide sleeves (71) in a sliding mode;

the second spring (78) is connected between the first guide sleeve (71) and the push rod (77);

the baffle plate (72) is welded with a first rack (79), and the first rack (79) is welded on one side of the baffle plate (72);

the second guide sleeves (710), the second guide sleeves (710) are uniformly installed on the first guide sleeves (71) at intervals;

the sliding rods (712) are arranged in the second guide sleeves (710) in a sliding manner, and the sliding rods (712) are in fit contact with the third connecting rods (73);

the third spring (711) is connected between the sliding rod (712) and the second guide sleeve (710);

the sliding rod (712) is provided with a first rack (79), one end of the sliding rod (712) is provided with the one-way gear (713) in a rotating mode, and the one-way gear (713) is meshed with the first rack (79).

5. The device for quantitatively and synchronously discharging the multiple raw materials for producing the ceramsite according to claim 4, further comprising:

the limiting rod (8), the limiting rod (8) is connected to one end of the L-shaped rack (611);

square piece (9), square piece (9) are connected on first commentaries on classics board (62), square piece (9) with gag lever post (8) cooperation contact.