CN214288749U - High-efficient deironing device is used in refractory material production - Google Patents

Abstract

The utility model belongs to the technical field of the refractory material production deironing, especially, a refractory material production is with high-efficient deironing device, the following scheme is proposed at present, including first shell, first shell top is fixed with the second shell, the second shell top is fixed with the third shell through the support column, the cavity internally mounted that forms between second shell and the third shell has the deironing subassembly, first shell internally mounted has grinding assembly. The utility model discloses in the grinding subassembly through setting up drive the electro-magnet and rotate in the raw materials inside that does not grind, adsorb the iron impurity of mixing in the raw materials inside, after the deironing step is accomplished, one hundred eighty degrees in the electro-magnet upset, the iron impurity of being convenient for gets into in the draft tube to discharge along first guide plate, grinding subassembly grinds the raw materials of accomplishing the deironing step simultaneously, the raw materials after the deironing can not lead to the fact the damage to grinding roller, the life of grinding roller has been prolonged.

Description

High-efficient deironing device is used in refractory material production

Technical Field

The utility model relates to a refractory material produces deironing technical field, especially relates to a refractory material production is with high-efficient deironing device.

Background

Firebrick is called firebrick for short, is the refractory material who burns with fire clay or other refractory raw materials, need carry out broken grinding to the raw materials when firebrick produces, but present firebrick lacks the deironing step at the production process, leads to mixing the iron impurity damage grinding roller in raw materials inside, leads to grinding roller's life shorter, for this needs a refractory material production to use high-efficient deironing device.

SUMMERY OF THE UTILITY MODEL

The utility model provides a high-efficient deironing device is used in refractory material production has solved the problem that exists among the prior art.

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

a high-efficiency iron removal device for refractory material production comprises a first shell, wherein a second shell is fixed at the top end of the first shell, a third shell is fixed at the top end of the second shell through a supporting column, an iron removal assembly is arranged in a cavity formed between the second shell and the third shell, and a grinding assembly is arranged in the first shell;

the deironing subassembly cup joints the annular drive plate in the inside of second shell including rotating, the drive plate bottom mounting has the ring gear, the honeycomb duct has been cup jointed in the inside rotation of drive plate, the honeycomb duct internal fixation has first guide plate, the honeycomb duct external fixation has the second guide plate, first guide plate top bottom both ends are fixed with first electro-magnet and second electro-magnet through multistage telescopic link respectively, honeycomb duct outside one end is connected with first driving motor through the actuating lever, first driving motor bottom mounting has the control box, the control box bottom end is fixed with the slider, the second shell outside is fixed with the backup pad that the cooperation slider slided and uses.

Preferably, the grinding assembly comprises a second driving motor fixed in the middle of the top end of the first shell, a grinding roller is fixed at the output end of the second driving motor, a first gear is fixed at the position, located at the top end of the first shell, of the grinding roller, a second gear is meshed and connected to the outer side of the first gear, a third gear is fixed in the middle of the second gear through a connecting rod, and the third gear is meshed and connected with the toothed ring.

Preferably, the second shell outside is fixed with connects the silo, it is the ring form to connect the silo, connect the silo to have seted up the drain hole, the second shell bottom is the slope form, the ejection of compact pipeline has been inlayed to second shell bottom, the discharge gate has been seted up at first shell bottom middle part, the inside solenoid valve that all installs with the discharge gate inside of ejection of compact pipeline, the feed inlet has been seted up to third shell top one side, the inside feed inlet below position department that is located of third shell installs the crushing roller.

Preferably, the guide pipe is externally sleeved with a pulley in a rotating mode, and sliding grooves matched with the pulley to rotate are formed in the top end of the second shell and the bottom end of the third shell.

Preferably, the multistage telescopic rod is internally provided with a return spring, and the multistage telescopic rod increases in stages along the extension direction of the first guide plate towards the two ends.

Preferably, power source, controller, battery, signal transmission module, signal receiving module and data interface are installed to inside one side of control box, the controller adopts the ARM singlechip, controller and first electro-magnet, second electro-magnet, first driving motor, second driving motor, solenoid valve and crushing roller electric connection, the battery output is connected with power source.

The utility model discloses in the grinding subassembly through setting up drive the electro-magnet and rotate in the raw materials inside that does not grind, adsorb the iron impurity of mixing in the raw materials inside, after the deironing step is accomplished, one hundred eighty degrees in the electro-magnet upset, the iron impurity of being convenient for gets into in the draft tube to discharge along first guide plate, grinding subassembly grinds the raw materials of accomplishing the deironing step simultaneously, the raw materials after the deironing can not lead to the fact the damage to grinding roller, the life of grinding roller has been prolonged.

Drawings

FIG. 1 is a sectional view of the overall structure of a high-efficiency iron removing device for producing refractory materials according to the present invention;

FIG. 2 is a schematic view of a ring gear mounting structure of the high-efficiency iron removing device for producing refractory material of the present invention;

FIG. 3 is a schematic view of a second deflector of the high-efficiency de-ironing device for producing refractory material of the present invention;

fig. 4 is the utility model provides a third gear mounting structure plan view of high-efficient deironing device is used in refractory material production.

In the figure: 1. a first housing; 2. a second housing; 3. a third housing; 4. an iron removal assembly; 41. A drive plate; 42. a toothed ring; 43. a flow guide pipe; 44. a first baffle; 45. a second baffle; 46. a multi-stage telescopic rod; 47. a first electromagnet; 48. a second electromagnet; 49. a first drive motor; 410. a control box; 5. a grinding assembly; 51. a second drive motor; 52. a grinding roller; 53. a first gear; 54. a second gear; 55. a third gear; 6. a material receiving groove; 7. A discharge pipeline; 8. an electromagnetic valve.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

Referring to fig. 1-4, a high-efficiency iron removing device for refractory material production comprises a first shell 1, a second shell 2 is fixed at the top end of the first shell 1, a third shell 3 is fixed at the top end of the second shell 2 through a support column, an iron removing assembly 4 is installed in a cavity formed between the second shell 2 and the third shell 3, and a grinding assembly 5 is installed in the first shell 1;

the iron removing component 4 comprises an annular driving plate 41 rotatably sleeved inside the second shell 2, a toothed ring 42 is fixed at the bottom end of the driving plate 41, the annular driving plate 41 is driven by the toothed ring 42 to rotate inside the device, a guide pipe 43 is rotatably sleeved inside the driving plate 41, a first guide plate 44 is fixed inside the guide pipe 43, iron impurities entering the guide pipe 43 can be conveniently discharged from two ends of the guide pipe 43, a second guide plate 45 is fixed outside the guide pipe 43, the iron impurities can conveniently enter the guide pipe 43, a first electromagnet 47 and a second electromagnet 48 are respectively fixed at two ends of the top and bottom of the first guide plate 44 through a multi-stage telescopic rod 46, the first electromagnet 47 and the second electromagnet 48 fully adsorb the iron impurities mixed in the raw materials in the stirring process, a first driving motor 49 is connected at one end outside the guide pipe 43 through a driving rod, a control box 410 is fixed at the bottom end of the first driving motor 49, and a sliding block is fixed at the bottom end of the control box 410, a supporting plate used in cooperation with the sliding block is fixed on the outer side of the second housing 2, so that the control box 410 and the first driving motor 49 can rotate along with the flow guide pipe 43 on the outer side of the device.

The further grinding assembly 5 comprises a second driving motor 51 fixed at the middle of the top end of the first housing 1, a grinding roller 52 is fixed at the output end of the second driving motor 51, a first gear 53 is fixed at the position of the top end of the first housing 1 at the output end of the second driving motor 51, a second gear 54 is meshed and connected with the outer side of the first gear 53, a third gear 55 is fixed at the middle of the second gear 54 through a connecting rod, the third gear 55 is meshed and connected with the toothed ring 42, and the second driving motor 51 drives the toothed ring 42 to rotate through the first gear 53, the second gear 54 and the second gear 55, so as to drive the driving plate 41 and the first electromagnet 47 and the second electromagnet 48 to rotate.

Especially, 2 outsides of second shell are fixed with and are used for holding connecing silo 6 of iron impurity, it is the ring form to connect silo 6, connect silo 6 to have seted up the drain hole, 2 bottoms of second shell are the slope form, the raw materials of being convenient for get into 1 inside grinding of first shell, discharge tube 7 has been inlayed to 2 bottoms of second shell, the discharge gate has been seted up at 1 bottom middle part of first shell, discharge tube 7 is inside all installs solenoid valve 8 with the discharge gate is inside, the feed inlet has been seted up to 3 top one sides of third shell, 3 inside feed inlet below positions department that lie in of third shell installs and is used for carrying out broken crushing roller to the raw materials.

It is worth to explain that the guide pipe 43 is externally rotatably sleeved with a pulley, and the top end of the second housing 2 and the bottom end of the third housing 3 are both provided with sliding chutes matched with the pulley for rotation, so that the driving plate 41 can conveniently rotate inside the second housing 2 and inside the third housing 3.

In addition, the multi-stage telescopic rod 46 is internally provided with a return spring, and the multi-stage telescopic rod 46 increases in stages along the extension direction of the first guide plate 44 towards the two ends, so that when the first driving motor 49 drives the flow guide pipe 43 to rotate, the inner wall of the second housing 2 does not influence the rotation of the electromagnet.

Besides, a power interface, a controller, a storage battery, a signal transmitting module, a signal receiving module and a data interface are installed on one side inside the control box 410, the controller adopts an ARM single chip microcomputer, the controller is electrically connected with the first electromagnet 47, the second electromagnet 48, the first driving motor 49, the second driving motor 51, the electromagnetic valve and the crushing roller, and the output end of the storage battery is connected with the power interface.

The working principle is as follows: when the device is used, before the raw material is guided into the second shell 2 through the feeding hole, the first driving motor 49 is started, the first driving motor 49 drives the flow guide pipe 43 to rotate ninety degrees, so that the first electromagnet 47 and the second electromagnet 48 are in a horizontal state, the multi-stage telescopic rod 46 drives the bottom ends of the first electromagnet 47 and the second electromagnet 48 to rotate along the inner walls of the second shell 2 and the third shell 3 in the process that the flow guide pipe 43 is driven by the first driving motor 49 to rotate, the multi-stage telescopic rod 46 which is closer to the end part of the flow guide pipe 43 is shortened, then the raw material is poured in, the raw material is crushed by the crushing roller, after the raw material is completely poured in, the crushing roller stops working, then the flow guide pipe 43 is driven by the first driving motor 49 to rotate ninety degrees in the reverse direction, the multi-stage telescopic rod 46 is extended in the rotating process until the bottom end of the first electromagnet 47 is contacted with the bottom end of the second shell 2, at the moment, the first electromagnet 47 is powered on, the second electromagnet 48 is in a power-off state, when the second driving motor 51 drives the grinding roller 52 to grind the raw materials which have been subjected to the iron removing step, meanwhile, the first gear 53 drives the third gear 55 to rotate through the second gear 54, the third gear 55 drives the gear ring 42 to rotate, as the gear ring 42 is fixedly connected with the driving plate 41, the driving plate 41 and the flow guide pipe 43 are driven to rotate together, the first electromagnet 47 stirs the raw materials inside, the iron mixed inside the raw materials is adsorbed outside the first electromagnet 47, and iron impurities are fully adsorbed in the stirring process, when the raw materials in the first shell 1 are ground, the second driving motor 51 stops rotating, the single chip microcomputer receives a signal to control the first driving motor 49 to rotate for one hundred and eighty degrees, at the moment, the first electromagnet 47 is positioned right above the second electromagnet 48, the first electromagnet 47 is powered off, the second electromagnet 48 is powered on, after 47 outage of first electro-magnet, iron impurity drops, from second guide plate 45 surperficial landing to honeycomb duct 43 inside, again from 45 surperficial landing to honeycomb duct 43 both ends landing on second guide plate, finally drop to connect in the silo 6 from honeycomb duct 43 both ends, open the inside solenoid valve of first shell 1 earlier, grind the raw materials discharge of accomplishing, then close the solenoid valve in the first shell 1, open the inside solenoid valve of ejection of compact pipeline 7, make the raw materials of accomplishing the deironing step get into inside first shell 1, prepare to grind.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and to simplify the description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be construed as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically limited otherwise.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (6)

1. The efficient iron removal device for the production of the refractory materials comprises a first shell (1) and is characterized in that a second shell (2) is fixed to the top end of the first shell (1), a third shell (3) is fixed to the top end of the second shell (2) through a supporting column, an iron removal assembly (4) is installed inside a cavity formed between the second shell (2) and the third shell (3), and a grinding assembly (5) is installed inside the first shell (1);

the iron removing component (4) comprises an annular driving plate (41) which is rotatably sleeved in the second shell (2), a toothed ring (42) is fixed at the bottom end of the driving plate (41), a guide pipe (43) is rotatably sleeved in the driving plate (41), a first guide plate (44) is fixed inside the guide pipe (43), a second guide plate (45) is fixed outside the guide pipe (43), the top and bottom ends of the first guide plate (44) are respectively fixed with a first electromagnet (47) and a second electromagnet (48) through a multi-stage telescopic rod (46), one end of the outer side of the guide pipe (43) is connected with a first driving motor (49) through a driving rod, a control box (410) is fixed at the bottom end of the first driving motor (49), a sliding block is fixed at the bottom end of the control box (410), and a supporting plate which is matched with the sliding block to slide is fixed on the outer side of the second shell (2).

2. The device for removing iron efficiently in refractory production according to claim 1, wherein the grinding assembly (5) comprises a second driving motor (51) fixed at the middle of the top end of the first casing (1), the output end of the second driving motor (51) is fixed with a grinding roller (52), the second driving motor (51) is fixed with a first gear (53) at the top end of the first casing (1), the outer side of the first gear (53) is connected with a second gear (54) in a meshing manner, the middle of the second gear (54) is fixed with a third gear (55) through a connecting rod, and the third gear (55) is connected with a toothed ring (42) in a meshing manner.

3. The efficient iron removal device for refractory production according to claim 1, wherein a receiving trough (6) is fixed to the outer side of the second shell (2), the receiving trough (6) is circular, a discharging hole is formed in the receiving trough (6), the bottom end of the second shell (2) is inclined, a discharging pipeline (7) is embedded in the bottom end of the second shell (2), a discharging hole is formed in the middle of the bottom end of the first shell (1), electromagnetic valves (8) are installed inside the discharging pipeline (7) and the discharging hole, a feeding hole is formed in one side of the top end of the third shell (3), and a crushing roller is installed at a position below the feeding hole inside the third shell (3).

4. The efficient iron removal device for refractory production according to claim 1, wherein pulleys are rotatably sleeved outside the draft tube (43), and chutes matched with the pulleys to rotate are formed in the top end of the second casing (2) and the bottom end of the third casing (3).

5. The efficient iron removal device for refractory production according to claim 1, wherein a return spring is installed inside the multi-stage telescopic rod (46), and the stages of the multi-stage telescopic rod (46) increase along the extension direction of the first guide plate (44) to two ends.

6. The device for removing iron in refractory material production according to claim 1, wherein a power interface, a controller, a storage battery, a signal transmitting module, a signal receiving module and a data interface are installed on one side inside the control box (410), the controller adopts an ARM single chip microcomputer, the controller is electrically connected with the first electromagnet (47), the second electromagnet (48), the first driving motor (49), the second driving motor (51), the electromagnetic valve and the crushing roller, and the output end of the storage battery is connected with the power interface.

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