CN212638759U - Belt transmission device with deironing function - Google Patents

Abstract

The utility model discloses a belt transmission device with iron removal function, which comprises an iron removal device and a transmission device; the conveying device comprises a rack, wherein a plurality of groups of flat carrier rollers are mounted on the rack, and belts are sleeved on the plurality of groups of flat carrier rollers; the iron removing device comprises a mounting rack, an electromagnet is slidably mounted on the mounting rack, and the electromagnet is positioned above the belt; a collecting box is arranged below the mounting rack and is positioned on the side surface of the rack; the mounting frame is also provided with a power supply, a controller and a driving mechanism, and the driving mechanism is used for driving the electromagnet to axially move on the mounting frame along the flat carrier roller; the controller is used for controlling the working state of the driving mechanism and controlling the on/off of the electromagnet; the power supply supplies power for the controller and the driving mechanism. The utility model discloses can realize uninterruptedly carrying out the deironing to the material on the conveyer belt, when having guaranteed the deironing rate, can not influence production efficiency.

Description

Belt transmission device with deironing function

Technical Field

The utility model belongs to the technical field of belt transmission equipment, specifically a belt transmission device with deironing function.

Background

An electromagnetic iron remover is an electromagnetic device used for removing iron parts in bulk nonmagnetic materials, and is generally arranged at the head or the middle part of a belt conveyor. The strong magnetic force generated by electrifying can suck the iron pieces mixed in the materials and then throw the iron pieces out of the iron unloading belt, thereby achieving the purpose of automatic cleaning, effectively preventing the conveyor belt from longitudinally scratching and cracking and protecting the normal work of a crusher, a grinder, a flat plate iron remover and the like.

At present, the chinese utility model patent of bulletin number CN206778697U discloses an intelligent electromagnetism de-ironing separator for cement manufacture line, including metal detection instrument and battery deironing device, the metal detection instrument passes through support fixed mounting in cement conveyer belt body top, battery deironing device is including hanging subassembly and electromagnet assembly, it includes support, height adjusting bolt, a set of wire rope, casing and a set of rings to hang the subassembly, height adjusting bolt's one end is connected on the support. The iron pieces and the iron blocks mixed in the cement are absorbed to the electromagnet assembly by utilizing the magnetic force of the electromagnet, so that the aim of removing the iron pieces in the cement is fulfilled.

However, among the above-mentioned technical scheme, need use when the iron part on the electro-magnet assembly is absorbent enough to hang the subassembly and remove the electro-magnet assembly to one side and will adsorb and lift off in the electro-magnet assembly iron part, just can the rework, and at this in-process, intelligence electromagnetism de-ironing separator can not carry out the deironing work to need the cement conveyer belt to stop, thereby influence production efficiency.

Disclosure of Invention

The utility model aims at providing a belt transmission device with deironing function to the problem that prior art exists, can realize uninterruptedly carrying out the deironing to the material on the conveyer belt, when having guaranteed the deironing rate, can not influence production efficiency.

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

a belt transmission device with a deironing function comprises a deironing device and a transmission device; the conveying device comprises a rack, wherein a plurality of groups of flat carrier rollers are mounted on the rack, and belts are sleeved on the plurality of groups of flat carrier rollers;

the iron removing device comprises a mounting rack, an electromagnet is slidably mounted on the mounting rack, and the electromagnet is positioned above the belt; a collecting box is arranged below the mounting rack and is positioned on the side surface of the rack; the mounting frame is also provided with a power supply, a controller and a driving mechanism, and the driving mechanism is used for driving the electromagnet to axially move on the mounting frame along the flat carrier roller; the controller is used for controlling the working state of the driving mechanism and controlling the on/off of the electromagnet; the power supply supplies power for the controller and the driving mechanism.

Specifically, the mounting bracket includes the mounting panel, the mounting panel bottom is equipped with 4 spinal branch vaulting poles, the mounting panel is located the belt top.

Specifically, the electromagnet comprises a first electromagnet and a second electromagnet, and one end of the first electromagnet is fixedly connected with one end of the second electromagnet; a sliding assembly is arranged at the connecting part of the first electromagnet and the second electromagnet; the first electromagnet and the second electromagnet are respectively connected with the controller;

a hole groove is formed in the middle of the mounting plate, and the slotting direction of the hole groove is consistent with the axial direction of the flat carrier roller; the middle part of the sliding component is movably embedded in the hole groove; the output end of the driving mechanism is connected with the sliding assembly and used for driving the sliding assembly to axially move in the hole groove along the flat carrier roller.

Specifically, the sliding assembly sequentially comprises a sliding block, a connecting rod and a bottom plate from top to bottom, and the sliding block, the connecting rod and the bottom plate are sequentially and fixedly connected; the bottom plate is connected with the middle parts of the first electromagnet and the second electromagnet; the top of connecting rod inlays establishes in the hole groove, the slider is located the hole groove outside.

Specifically, the driving mechanism comprises a telescopic motor and a telescopic rod; and two ends of the telescopic rod are respectively connected with the slide block and the output end of the telescopic motor. The controller controls the telescopic motor to drive the telescopic rod to stretch, so that the first electromagnet and the second electromagnet move left and right above the belt along the axial direction of the flat carrier roller; meanwhile, the controller controls the first electromagnet and the second electromagnet to be powered on or off, so that the first electromagnet or the second electromagnet is used for discharging.

Specifically, the bottom of the sliding block is provided with a roller, the top surface of the mounting plate is provided with 2 sliding grooves, and the 2 sliding grooves are positioned on two sides of the hole groove and are parallel to the hole groove; the position and the size of the sliding groove are matched with those of the roller. The sliding block can move more smoothly by arranging the sliding groove.

Specifically, the collecting box comprises a first collecting box and a second collecting box, and the first collecting box and the second collecting box are respectively positioned on the left side and the right side of the rack. When the number of the iron pieces adsorbed at the bottom of the first electromagnet is too large, the first electromagnet and the second electromagnet are controlled to move leftwards, so that the first electromagnet is positioned above the first collecting box, the second electromagnet is positioned above the belt, and the second electromagnet adsorbs the iron pieces in the materials conveyed on the belt while the first electromagnet unloads the materials; in a similar way, when the number of the iron pieces adsorbed on the second electromagnet is too large, the second electromagnet is positioned above the second collecting box, and the first electromagnet is positioned above the belt, so that the seamless connection between the iron removing device and the transmission device is realized, and the iron removing efficiency and the production efficiency are improved.

Compared with the prior art, the beneficial effects of the utility model are that: the utility model discloses a set up 2 electro-magnets above the belt, and drive 2 electro-magnets through actuating mechanism and take turns to adsorb the ironware in the material that transports on the belt, when 1 electro-magnet among them is located the belt, 1 electro-magnet in addition is located the collecting box; controlling an electromagnet above the belt to conduct an iron piece in the adsorbed material through a controller, and controlling an electromagnet above the collecting box to be powered off to discharge the adsorbed iron piece into the collecting box; therefore, the electromagnet is not influenced by iron attraction and iron unloading, and the conveying device does not need to be stopped in the switching process of the iron attraction and the iron unloading, so that the production efficiency is improved.

Drawings

Fig. 1 is a schematic view of the overall structure of a belt transmission device with iron removal function according to the present invention;

fig. 2 is a schematic structural diagram of the transmission device of the present invention;

fig. 3 is a schematic structural view of the mounting frame of the present invention;

FIG. 4 is a schematic view of the installation structure of the sliding assembly and the electromagnet of the present invention;

FIG. 5 is a schematic side view of the telescopic rod of the embodiment of the present invention in an extended state;

fig. 6 is a schematic side view of the entire device in the retracted state of the telescopic rod according to the embodiment of the present invention;

in the figure: 1. a frame; 2. a flat carrier roller; 3. a belt; 4. a power source; 5. a controller; 6. mounting a plate; 7. a support bar; 8. a first electromagnet; 9. a second electromagnet; 10. a hole groove; 11. a slider; 12. a connecting rod; 13. a base plate; 14. a telescopic motor; 15. a telescopic rod; 16. a roller; 17. a chute; 18. a first collection tank; 19. a second collection tank.

Detailed Description

The technical solution of the present invention will be described clearly and completely with reference to the accompanying drawings, and obviously, the described embodiments are only some embodiments, not all embodiments of the present invention. Based on the embodiments of the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

As shown in fig. 1 and 2, the present embodiment provides a belt conveying device with iron removal function, which includes an iron removal device and a conveying device; the conveying device comprises a rack 1, wherein a plurality of groups of flat carrier rollers 2 are mounted on the rack 1, and belts 3 are sleeved on the plurality of groups of flat carrier rollers 2;

the iron removing device comprises a mounting rack, an electromagnet is slidably mounted on the mounting rack, and the electromagnet is positioned above the belt 3; a collecting box is arranged below the mounting rack and is positioned on the side surface of the rack 1; the mounting rack is also provided with a power supply 4, a controller 5 and a driving mechanism, and the driving mechanism is used for driving the electromagnet to axially move on the mounting rack along the flat carrier roller 2; the controller 5 is used for controlling the working state of the driving mechanism and controlling the on/off of the electromagnet; and the power supply 4 supplies power to the controller 5 and the driving mechanism.

Specifically, the mounting bracket includes mounting panel 6, mounting panel 6 bottom is equipped with 4 spinal branch vaulting poles 7, mounting panel 6 is located belt 3 top.

As shown in fig. 3 and 4, specifically, the electromagnets include a first electromagnet 8 and a second electromagnet 9, and one end of the first electromagnet 8 is fixedly connected with one end of the second electromagnet 9; a sliding component is arranged at the connecting part of the first electromagnet 8 and the second electromagnet 9; the first electromagnet 8 and the second electromagnet 9 are respectively connected with the controller 5;

a hole groove 10 is formed in the middle of the mounting plate 6, and the slotting direction of the hole groove 10 is consistent with the axial direction of the flat carrier roller 2; the middle part of the sliding component is movably embedded in the hole groove 10; the output end of the driving mechanism is connected with the sliding assembly and used for driving the sliding assembly to axially move along the flat carrier roller 2 in the hole groove 10.

Specifically, the sliding assembly sequentially comprises a sliding block 11, a connecting rod 12 and a bottom plate 13 from top to bottom, and the sliding block 11, the connecting rod 12 and the bottom plate 13 are sequentially and fixedly connected; the bottom plate 13 is connected with the middle parts of the first electromagnet 8 and the second electromagnet 9; the top of the connecting rod 12 is embedded in the hole groove 10, and the sliding block 11 is located outside the hole groove 10.

Specifically, the driving mechanism comprises a telescopic motor 14 and a telescopic rod 15; and two ends of the telescopic rod 15 are respectively connected with the output ends of the sliding block 11 and the telescopic motor 14. The controller 5 controls the telescopic motor 14 to drive the telescopic rod 15 to stretch, so that the first electromagnet 8 and the second electromagnet 9 move left and right above the belt 3 along the axial direction of the flat carrier roller 2; meanwhile, the controller 5 controls the first electromagnet 8 and the second electromagnet 9 to be powered on or powered off, so that the first electromagnet 8 or the second electromagnet 9 is used for discharging.

Specifically, the bottom of the sliding block 11 is provided with a roller 16, the top surface of the mounting plate 6 is provided with 2 sliding grooves 17, and the 2 sliding grooves 17 are positioned at two sides of the hole groove 10 and are parallel to the hole groove 10; the sliding groove 17 is matched with the roller 16 in position and size. The slide block 11 can be moved more smoothly by providing the slide groove 17.

Specifically, the collecting box comprises a first collecting box 18 and a second collecting box 19, and the first collecting box 18 and the second collecting box 19 are respectively positioned at the left side and the right side of the rack 1. When the number of the iron pieces adsorbed at the bottom of the first electromagnet 8 is too large, the first electromagnet 8 and the second electromagnet 9 are controlled to move leftwards, so that the first electromagnet 8 is positioned above the first collecting box 18, the second electromagnet 9 is positioned above the belt 3, and the second electromagnet 9 adsorbs the iron pieces in the materials conveyed on the belt 3 while the first electromagnet 8 unloads the materials; in a similar way, when the number of the iron pieces adsorbed on the second electromagnet 9 is too large, the second electromagnet 9 is positioned above the second collecting box 19, and the first electromagnet 8 is positioned above the belt 3, so that the seamless connection between the iron removing device and the transmission device is realized, and the iron removing efficiency and the production efficiency are improved.

Specifically, in this embodiment, the controller 5 may be implemented by a manual switch/button or an automatic control.

When the belt conveying device of the embodiment works, firstly, as shown in fig. 5, the first electromagnet 8 is positioned above the belt 3, the second electromagnet 9 is positioned above the second collecting box 19, the first electromagnet 8 is conducted to adsorb iron pieces in materials on the belt 3, and the second electromagnet 9 is in a power-off standby state; when the number of the iron pieces adsorbed by the first electromagnet 8 is too large, the controller 5 controls the second electromagnet 9 to be electrified, and simultaneously controls the telescopic motor 14 to drive the telescopic rod 15 to contract to drive the sliding block 11 to move leftwards, so that the first electromagnet 8 and the second electromagnet 9 are driven to move leftwards, when the first electromagnet 8 moves to the position above the first collecting box 18, the second electromagnet 9 is just positioned above the belt 3, as shown in fig. 6, and at the moment, the telescopic motor 14 stops running; then the first electromagnet 8 is controlled to be powered off, and at the moment, the iron piece adsorbed at the bottom of the first electromagnet 8 falls into the first collection box 18 due to the loss of magnetic force, so that the unloading of the first electromagnet 8 is realized; after the second electromagnet 9 is conducted, the first electromagnet 8 can be connected to adsorb iron pieces in the materials conveyed on the belt 3, the conveying device does not need to be stopped, and the production efficiency is greatly improved;

similarly, when the number of the iron pieces adsorbed by the second electromagnet 9 is too large, the controller 5 controls the first electromagnet 8 to be electrified, and simultaneously controls the telescopic motor 14 to drive the telescopic rod 15 to extend to drive the sliding block 11 to move rightwards, so that the first electromagnet 8 and the second electromagnet 9 are driven to move rightwards, when the second electromagnet 9 moves to the position above the second collecting box 19, the first electromagnet 8 is just positioned above the belt 3, and at the moment, the telescopic motor 14 stops running; then the second electromagnet 9 is controlled to be powered off, and at the moment, the iron piece adsorbed at the bottom of the second electromagnet 9 falls into the second collection box 19 due to the loss of magnetic force, so that the second electromagnet 9 is unloaded; and the first electromagnet 8 can be connected with the second electromagnet 9 to adsorb the iron pieces in the materials transmitted on the belt 3 after being conducted.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. A belt transmission device with a deironing function comprises a deironing device and a transmission device; the conveying device comprises a rack, wherein a plurality of groups of flat carrier rollers are mounted on the rack, and belts are sleeved on the plurality of groups of flat carrier rollers; it is characterized in that the preparation method is characterized in that,

the iron removing device comprises a mounting rack, an electromagnet is slidably mounted on the mounting rack, and the electromagnet is positioned above the belt; a collecting box is arranged below the mounting rack and is positioned on the side surface of the rack; the mounting frame is also provided with a power supply, a controller and a driving mechanism, and the driving mechanism is used for driving the electromagnet to axially move on the mounting frame along the flat carrier roller; the controller is used for controlling the working state of the driving mechanism and controlling the on/off of the electromagnet; the power supply supplies power for the controller and the driving mechanism.

2. The belt conveying device with the iron removing function as claimed in claim 1, wherein the mounting rack comprises a mounting plate, 4 support rods are arranged at the bottom of the mounting plate, and the mounting plate is located above the belt.

3. The belt conveying device with the iron removing function as claimed in claim 2, wherein the electromagnet comprises a first electromagnet and a second electromagnet, and one end of the first electromagnet is fixedly connected with one end of the second electromagnet; a sliding assembly is arranged at the connecting part of the first electromagnet and the second electromagnet; the first electromagnet and the second electromagnet are respectively connected with the controller;

a hole groove is formed in the middle of the mounting plate, and the slotting direction of the hole groove is consistent with the axial direction of the flat carrier roller; the middle part of the sliding component is movably embedded in the hole groove; the output end of the driving mechanism is connected with the sliding assembly and used for driving the sliding assembly to axially move in the hole groove along the flat carrier roller.

4. The belt conveying device with the iron removing function as claimed in claim 3, wherein the sliding assembly sequentially comprises a sliding block, a connecting rod and a bottom plate from top to bottom, and the sliding block, the connecting rod and the bottom plate are sequentially and fixedly connected; the bottom plate is connected with the middle parts of the first electromagnet and the second electromagnet; the top of connecting rod inlays establishes in the hole groove, the slider is located the hole groove outside.

5. The belt conveyer with iron removal function as claimed in claim 3, wherein said driving mechanism comprises a telescopic motor and a telescopic rod; and two ends of the telescopic rod are respectively connected with the slide block and the output end of the telescopic motor.

6. The belt conveying device with the iron removing function as claimed in claim 4, wherein the bottom of the sliding block is provided with a roller, the top surface of the mounting plate is provided with 2 sliding grooves, and the 2 sliding grooves are positioned on two sides of the hole groove and are parallel to the hole groove; the position and the size of the sliding groove are matched with those of the roller.

7. The belt conveyer with iron removing function as claimed in claim 3, wherein said collection box comprises a first collection box and a second collection box, said first collection box and said second collection box are respectively located at the left and right sides of the frame.

Images