CN108043576B - Iron removing device - Google Patents

Abstract

The invention discloses an iron removing device, and relates to a device for removing iron contained in materials, which comprises: a housing; the fixed tubes are arranged in the shell at intervals in the vertical direction, the number of the fixed tubes in the odd-numbered layers of the fixed tubes is five, the number of the fixed tubes in the even-numbered layers of the fixed tubes is four, and a first through hole is formed in the shell at a position opposite to the other end of each fixed tube; the material distributing plate is positioned above the multilayer fixed pipes, the middle part of the material distributing plate is higher, two ends of the material distributing plate gradually incline downwards, and the middle part of the material distributing plate is provided with a first opening; the magnetic cores are equal to the fixed tubes in number and correspond to the fixed tubes one by one, one ends of the magnetic cores penetrate through the first through holes and are inserted into the corresponding fixed tubes, and the other ends of the magnetic cores are located outside the shell. The invention can lead the fixed pipe to be convenient to clean after adsorbing scrap iron, lead the material to be easy to disperse and improve the iron removal efficiency.

Description

Iron removing device

Technical Field

The invention relates to a device for removing iron contained in materials. More specifically, the present invention relates to an iron removal device.

Background

In the fields of ceramics, abrasive materials, mineral powder, papermaking, chemical industry and the like, powder or slurry can carry particles such as scrap iron and the like, the scrap iron can be mixed in the processing and storage processes, the quality of products can be reduced due to the existence of the scrap iron, processing equipment can be damaged, and therefore an iron removal device is required to be adopted for removing iron.

The existing iron removing device has the problems that the iron core is not easy to clean after being adsorbed with iron chips, and materials are not easy to disperse, so that the iron removing efficiency is low.

Disclosure of Invention

The invention aims to provide an iron removal device, so that a fixed pipe can be conveniently cleaned after adsorbing scrap iron, materials are easy to disperse, and the iron removal efficiency is improved.

To achieve these objects and other advantages in accordance with the present invention, there is provided an iron removing apparatus comprising:

the device comprises a shell, a first guide rail, a second guide rail, a first guide rail and a second guide rail, wherein the shell is in a hollow cuboid shape, a feed port is formed in the top of the shell, a discharge port is formed in the bottom of the shell, and a;

the fixed pipe of multilayer, it sets up along vertical direction interval the inside of casing, every layer of fixed pipe comprises many fixed pipes, and many fixed pipes are followed the equidistant setting of width direction of casing, every layer of fixed pipe for the axis symmetry of casing sets up, and every fixed pipe is followed the length direction of casing sets up, the one end of fixed pipe with a lateral wall fixed connection of casing, the other end with another lateral wall fixed connection of casing, just on the casing with the relative position department of the other end of fixed pipe is provided with first through-hole, from the top down, and the number of fixed pipe in the fixed pipe of odd number layer is five, and the inside cavity that is located the fixed pipe in the outside, both ends open, the cross section is right angle isosceles right triangle to its one side with the inside wall of casing pastes and fixed connection mutually, from the top down, and the inclined plane of the fixed pipe that is located the outside in the fixed pipe of odd number layer is from being close to one side of casing is kept away from towards one side of casing is kept away from One side of the shell is gradually inclined downwards, other fixed pipes except the fixed pipes positioned on the outer side are hollow, two ends of the fixed pipes are open, the cross sections of the fixed pipes are isosceles triangles, from top to bottom, the number of the fixed pipes in the fixed pipes on the even number layer is four, each fixed pipe is hollow, two ends of the fixed pipe are open, the cross section of the fixed pipe is isosceles triangle, and from top to bottom, the vertex angle of the fixed pipe in the fixed pipe on the even number layer is opposite to the part between the two fixed pipes in the fixed pipes on the odd number layer;

the material distributing plate is arranged inside the shell and located above the multiple layers of fixed pipes, the middle of the material distributing plate is higher, two ends of the material distributing plate respectively incline downwards towards the two side walls arranged on the shell at intervals along the width direction of the shell and are not in contact with the two side walls arranged on the shell at intervals along the width direction of the shell, the middle of the material distributing plate is not in contact with the top of the shell and is provided with a first opening, the first opening is opposite to the center of the top of the shell, the size of the first opening is smaller than that of the feed inlet, two ends of the material distributing plate are both rectangular, two tail ends of the material distributing plate are respectively located above two fixed pipes adjacent to the middle fixed pipe in the fixed pipe at the topmost layer or above two fixed pipes at the outer side, two side edges of the material distributing plate arranged at intervals along the length direction of the shell are respectively located above two side walls arranged on the shell at intervals along the length direction of the fixed pipe Fixed and connected seamlessly;

the magnetic cores are equal to the fixed tubes in number and correspond to one another, one ends of the magnetic cores penetrate through the first through holes and are inserted into the corresponding fixed tubes, and the other ends of the magnetic cores are located outside the shell.

Preferably, in the iron removing device, two ends of the material distributing plate are respectively located above two adjacent fixed pipes of the topmost fixed pipe and the middle fixed pipe.

Preferably, the iron removing device further includes:

the two baffles are symmetrically arranged relative to the axis of the shell, two tail ends of the material distribution plate are opposite to one baffle respectively and do not contact with the other baffle, one end of each baffle is fixedly connected with the top of the shell, the other end of each baffle extends to the lower portion of the material distribution plate and is positioned above the fixed pipe which is positioned in the fixed pipe at the topmost layer and adjacent to the fixed pipe in the middle, each baffle is rectangular, and two sides of each baffle, which are arranged at intervals in the length direction of the shell, are fixed to two side walls of the shell at intervals in the length direction of the shell respectively and are connected seamlessly.

Preferably, in the iron removal device, the number of layers of the fixed pipe is an odd number of layers, and a square second through hole is formed in one side wall of the shell;

the deironing device still includes:

the tank body is cuboid, the opening of the tank body is upward, the size of the cross section of the tank body is the same as that of the second through hole, one end of the tank body penetrates through the second through hole, when one end of the tank body is in contact with the other side wall of the shell, the other end of the tank body is positioned outside the shell, and a gap between two adjacent fixed pipes in the fixed pipe at the bottommost layer is opposite to the tank body;

the connecting rod, it is located in the casing, and follow the length direction of casing sets up, the one end of connecting rod with the one end fixed connection of cell body, the other end passes another lateral wall of casing, and is located the outside of casing.

Preferably, the iron removing device further includes:

a linear guide rail extending in a longitudinal direction of the housing;

and the sliding blocks are respectively and fixedly connected with the other ends of the magnetic cores and the other end of the connecting rod, and the sliding blocks are positioned on the linear guide rail.

Preferably, the iron removing device further includes:

and the driving device is connected with the sliding block and is used for driving the sliding block to reciprocate on the linear guide rail.

Preferably, the iron removing device further includes:

and the two limiting plates are fixedly arranged at the top of one end and the other end of the groove body respectively.

The invention at least comprises the following beneficial effects:

according to the invention, the materials are dispersed through the material distributing plate and then are contacted with the multiple layers of fixed pipes, so that scrap iron in the materials is easy to adsorb on the fixed pipes, and after more scrap iron is adsorbed on the fixed pipes, the scrap iron on the fixed pipes can fall into the groove body only by outwards and simultaneously drawing out the magnetic cores and the connecting rods, so that repeated dismounting and mounting of the material output pipes are avoided, and time and labor are saved.

According to the invention, the fixed pipe is set to be in a right-angled triangle or isosceles triangle, so that the contact area between the materials and the fixed pipe is increased, the materials are not accumulated on the fixed pipe, and the iron removal efficiency is greatly improved.

Additional advantages, objects, and features of the invention will be set forth in part in the description which follows and in part will become apparent to those having ordinary skill in the art upon examination of the following or may be learned from practice of the invention.

Drawings

FIG. 1 is a schematic structural view of an iron removing apparatus according to an embodiment of the present invention;

fig. 2 is a schematic structural view of a material distributing plate according to an embodiment of the present invention.

Detailed Description

The present invention is further described in detail below with reference to the attached drawings so that those skilled in the art can implement the invention by referring to the description text.

It should be noted that in the description of the present invention, the terms "lateral", "longitudinal", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc. indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the referred device or element must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

As shown in fig. 1 and 2, the present invention provides an iron removing apparatus, including:

the device comprises a shell 100, a first cover, a second cover and a first cover, wherein the shell 100 is in a hollow cuboid shape, a feeding hole 101 is formed in the top of the shell 100, a discharging hole 102 is formed in the bottom of the shell 102, the discharging hole 102 is in a funnel shape, and a plurality of first through holes are formed in the shell 100 at intervals;

a plurality of layers of fixed tubes 110 disposed inside the casing 100 at intervals in a vertical direction, each layer of fixed tubes 110 being composed of a plurality of fixed tubes 110, the plurality of fixed tubes 110 being disposed at equal intervals in a width direction of the casing 100, each layer of fixed tubes 110 being disposed symmetrically with respect to an axis of the casing 100, each fixed tube 110 being disposed in a length direction of the casing 100, one end of each fixed tube 110 being fixedly connected to one sidewall (left sidewall, as shown in fig. 1) of the casing 100, the other end being fixedly connected to the other sidewall (right sidewall, as shown in fig. 1) of the casing 100, and a first through hole being disposed at a position of the casing 100 opposite to the other end of the fixed tube 110, so that the magnet core 130 can be inserted into the fixed tube 110 after passing through the first through hole, as shown in fig. 2, from top to bottom, the number of the fixed tubes 110 in the odd layers of fixed tubes 110 is five, and the fixing tubes 110 positioned at the outer side are hollow inside, open at both ends, and isosceles right triangle in cross section, and one right-angle side thereof is attached and fixedly connected with the inner side wall of the housing 100, from top to bottom, the inclined plane of the fixing tube 110 positioned at the outer side among the odd-numbered layers of fixing tubes 110 is gradually inclined downwards from the side close to the housing 100 to the side far from the housing 100, and the other fixing tubes 110 except the fixing tube 110 positioned at the outer side among the odd-numbered layers of fixing tubes 110 are hollow inside, open at both ends, and isosceles triangle in cross section, from top to bottom, the number of the fixing tubes 110 in the even-numbered layers of fixing tubes 110 is four, and each of the fixing tubes is hollow inside, open at both ends, and isosceles triangle in cross section, from top to bottom, the top corners of the fixing tubes 110 in the even-numbered layers of fixing tubes 110 are respectively opposite to the portion between two fixing tubes 110 in the odd-numbered layers of fixing tubes, therefore, the materials falling from the two fixed pipes 110 in the odd-numbered layers of fixed pipes 110 can be continuously dispersed through the fixed pipes below the fixed pipes, and the iron filings are adsorbed;

a material distributing plate 120 disposed inside the casing 100 and above the plurality of layers of fixed tubes 110, wherein the material distributing plate 120 has a higher middle portion, two ends of the material distributing plate respectively incline downwards towards two side walls spaced apart from the casing 100 along the width direction thereof, and do not contact with (are spaced apart from) two side walls spaced apart from the casing 100 along the width direction thereof, the middle portion of the material distributing plate 120 does not contact with the top of the casing 100, and is provided with a first opening 121, the first opening 121 is opposite to the center of the top of the casing 100 (or the top corner of the fixed tube 110 located at the middle of the topmost fixed tube 110), the size of the first opening 121 is smaller than the size of the material inlet 101 (such that after the material enters from the material inlet 101, a part of the material passes through the first opening 121, and the other part of the material falls along the material distributing plate 120 to the fixed tube 110 adjacent to the middle fixed tube 110), the two ends of the material distributing plate 120 are both rectangular, the two ends of the material distributing plate 120 are respectively located above two fixed tubes 110 (as shown in fig. 2, the second and fourth fixed tubes 110 from left to right in the top-most fixed tube 110) adjacent to the middle fixed tube 110 in the top-most fixed tube 110 or above two fixed tubes 110 (as shown in fig. 2, the first and fifth fixed tubes 110 from left to right in the top-most fixed tube 110), which are located at the outer side, and the two side edges of the material distributing plate 120, which are arranged at intervals along the length direction of the casing 100, are respectively fixed with the two side walls of the casing 100, which are arranged at intervals along the length direction, and are connected in a seamless manner;

the plurality of magnetic cores 130 are equal to the number of the fixing tubes 110 and are in one-to-one correspondence, one ends of the magnetic cores 130 pass through the first through holes and are inserted into the corresponding fixing tubes 110, and the other ends of the magnetic cores 130 are located outside the housing 100, so that the magnetic cores 130 are conveniently taken out.

When the iron removing device provided by the scheme is used, each magnet core 130 is inserted into the corresponding fixed pipe 110, iron-containing materials (powder or slurry) enter the shell 100 from the feeding hole 101, a part of the iron-containing materials pass through the first opening 121 and then fall onto the fixed pipe 110 positioned in the middle of the topmost fixed pipe 110, the other part of the iron-containing materials fall onto the fixed pipe 110 adjacent to the middle fixed pipe 110 or onto the two fixed pipes 110 positioned on the outer side along the material distributing plate 120, the materials are dispersed, part of iron in the materials is attracted onto the topmost fixed pipe 110, and then the materials fall down and are continuously dispersed by the lower fixed pipe 110, so that the iron in the materials is continuously attracted, and the materials are discharged from the discharging hole 102 and conveyed to the next equipment through the material output pipe for treatment. When waiting that iron fillings on the fixed pipe 110 need be cleared up, only need pull down the material output tube, outwards take out each magnet core 130 and connecting rod 160 simultaneously, iron fillings can come out from discharge gate 102, later install the material output tube can.

In another technical solution, in the iron removing device, two ends of the material distributing plate 120 are respectively located above two fixed tubes 110 adjacent to the middle fixed tube 110 in the topmost fixed tube 110. After passing through the first opening 121, a part of the ferrous material falls onto the middle fixed pipe 110 in the topmost fixed pipe 110, and another part of the ferrous material falls onto the fixed pipe 110 adjacent to the middle fixed pipe 110 along the material distributing plate 120, so that the ferrous material is dispersed.

In another technical solution, the iron removing apparatus further includes:

two baffles 140 are symmetrically arranged with respect to the axis of the housing 100, two ends of the material distribution plate 120 are respectively opposite to one baffle 140 and do not contact with (are separated by a certain distance from) the other baffle 140, one end of the baffle 140 is fixedly connected to the top of the housing 100, the other end extends to the lower part of the material distribution plate 120 and is located above the fixed pipe 110 adjacent to the middle fixed pipe 110 in the fixed pipe 110 at the topmost layer, the baffle 140 is rectangular, and two side edges of the baffle 140 spaced along the length direction of the housing 100 are respectively fixed to two side walls of the housing 100 spaced along the length direction thereof and are connected seamlessly. Because another part of the material falls down along the material distributing plate 120, the part of the material can be inclined and fall under the inertia effect, and thus the utilization rate of the fixed pipe 110 is low. After the baffle 140 is arranged, the part of the material can vertically fall to the top of the fixed pipe 110 adjacent to the middle fixed pipe 110 in the fixed pipe 110 at the topmost layer after touching the baffle 140, and then downwards along the two inclined planes of the fixed pipe 110, so that the utilization rate of the fixed pipe 110 is highest, and the dispersion effect and the iron removal effect are best.

In another technical scheme, in the iron removal device, the number of layers of the fixed pipe 110 is an odd number, and a square second through hole 103 is formed in one side wall of the housing 100;

the deironing device still includes:

a slot 150 (like a drawer), which is rectangular and has an upward opening, wherein the cross section of the slot 150 has the same size as the second through hole 103, one end of the slot 150 passes through the second through hole 103, when one end of the slot 150 contacts with the other side wall of the housing 100, the other end of the slot 150 is located outside the housing 100, and a gap between two adjacent fixed tubes 110 in the fixed tube 110 at the bottom layer is opposite to the slot 150, so that when iron chips are collected, the iron chips can all fall into the slot 150;

and a connecting rod 160 located in the housing 100 and arranged along the length direction of the housing 100, wherein one end of the connecting rod 160 is fixedly connected with one end of the groove body 150, and the other end of the connecting rod passes through another side wall of the housing 100 and is located outside the housing 100.

If the discharge gate 102 of material and iron fillings is the same, when can lead to needs to collect iron fillings, need to pull down material output tube from discharge gate 102, set up iron fillings collection device in discharge gate 102 again, treat that iron fillings are collected and accomplish the back, need install material output tube, waste time and energy like this.

In use, as shown in fig. 1, the iron removing device according to this embodiment inserts each magnetic core 130 into the corresponding fixed tube 110, one end (right end as shown in fig. 1) of the trough body 150 seals the second through hole 103, the iron-containing material (powder or slurry) enters the shell 100 from the feeding hole 101, after a part of the iron-containing material passes through the first opening 121, falls onto the middle fixed pipe 110 among the topmost fixed pipes 110, and the other part of the material falls onto the fixed pipe 110 adjacent to the middle fixed pipe 110 or onto the two fixed pipes 110 located at the outer side along the material distributing plate 120, the material is dispersed, and part of iron in the material is attracted to the fixed pipe 110 at the topmost layer, and then the material is continuously dispersed by the fixed pipe 110 at the lower layer, and iron in the material is continuously sucked, and the material is discharged from the discharge port 102 and conveyed to the next equipment for treatment through a material output pipe. When waiting to fix iron fillings on pipe 110 and needing to clear up, only need outwards (as shown in fig. 1, right) take out each magnet core 130 and connecting rod 160 simultaneously, iron fillings on fixed pipe 110 can fall into the cell body 150, have avoided dismantling repeatedly and install the material output tube, labour saving and time saving.

In another technical solution, the iron removing apparatus further includes:

a linear guide 170 extending in a longitudinal direction of the housing 100;

and a slider 180 fixedly connected to the other end of each of the magnetic cores 130 and the other end of the connecting rod 160, respectively, wherein the slider 180 is positioned on the linear guide 170. Like this when iron fillings on fixed pipe 110 need be cleared up, only need promote slider 180, outwards take out each magnet core 130, connecting rod 160 drives the cell body 150 and gets into in casing 100 simultaneously, after the appeal is lost to iron fillings, drop to the cell body 150 in from fixed pipe 110, later insert each magnet core 130 in the fixed pipe 110 that corresponds, and make the one end of cell body 150 seal second through-hole 103 (resume as the state shown in fig. 1), later make the material carry out the deironing again in the casing 100.

In another technical solution, the iron removing apparatus further includes:

and the driving device is connected with the sliding block 180 and is used for driving the sliding block 180 to reciprocate on the linear guide rail 170. The driving device can be a motor, a cylinder and the like, and is connected with the controller when in use.

In another technical solution, the iron removing apparatus further includes:

and two limit plates 190 respectively fixedly arranged at the top of one end and the other end of the tank body 150. Therefore, the slot body 150 can be prevented from being pushed out of the housing 100 or pulled into the housing 100 too much, so that the second through hole 103 can be sealed after the slot body 150 is pushed out, and the slot body can not be pulled out of the linear guide rail to cause poor return when the slot body is pulled into the housing.

While embodiments of the invention have been described above, it is not limited to the applications set forth in the description and the embodiments, which are fully applicable in various fields of endeavor to which the invention pertains, and further modifications may readily be made by those skilled in the art, it being understood that the invention is not limited to the details shown and described herein without departing from the general concept defined by the appended claims and their equivalents.

Claims (3)

1. Deironing device, its characterized in that includes:

the device comprises a shell, a first guide rail, a second guide rail, a first guide rail and a second guide rail, wherein the shell is in a hollow cuboid shape, a feed port is formed in the top of the shell, a discharge port is formed in the bottom of the shell, and a; a square second through hole is formed in one side wall of the shell, and the second through hole is located below the plurality of first through holes;

the fixed pipe of multilayer, it sets up in the inside of casing along vertical direction interval, and every layer of fixed pipe comprises many fixed pipes, and many fixed pipes set up along the equidistant of width direction of casing, every layer of fixed pipe for the axis symmetry of casing sets up, every fixed pipe along the length direction of casing sets up, fixed pipe's one end with a lateral wall fixed connection of casing, the other end with another lateral wall fixed connection of casing, and the casing is provided with the first through-hole in the position department relative with the other end of fixed pipe, from the top down, the number of fixed pipe in the fixed pipe of odd number layer is five, and the fixed pipe that is located the outside is inside cavity, both ends open, the cross section is isosceles right triangle to one of them limit with the inside wall laminating and fixed connection of casing, from the top down, the inclined plane of the fixed pipe positioned at the outer side in the odd-numbered fixed pipes is gradually inclined downwards from one side close to the shell to one side far away from the shell, the other fixed pipes except the fixed pipe positioned at the outer side are hollow, two ends of the fixed pipes are open, the cross section of each fixed pipe is an isosceles triangle, the number of the fixed pipes in the even-numbered fixed pipes is four from top to bottom, each fixed pipe is hollow, two ends of the fixed pipes are open, the cross section of each fixed pipe is an isosceles triangle, and from top to bottom, the vertex angle of the fixed pipe in the even-numbered fixed pipes is opposite to the part between the two fixed pipes in the odd-numbered fixed pipes respectively; the number of layers of the fixed pipe is odd;

the material distributing plate is arranged inside the shell and located above the multiple layers of fixed pipes, the middle of the material distributing plate is higher, two ends of the material distributing plate respectively incline downwards towards the two side walls arranged on the shell at intervals along the width direction of the shell and are not in contact with the two side walls arranged on the shell at intervals along the width direction of the shell, the middle of the material distributing plate is not in contact with the top of the shell and is provided with a first opening, the first opening is opposite to the center of the top of the shell, the size of the first opening is smaller than that of the feed inlet, two ends of the material distributing plate are both rectangular, two tail ends of the material distributing plate are respectively located above two fixed pipes adjacent to the middle fixed pipe in the fixed pipe at the topmost layer or above two fixed pipes at the outer side, two side edges of the material distributing plate arranged at intervals along the length direction of the shell are respectively located above two side walls arranged on the shell at intervals along the length direction of the fixed pipe Fixed and connected seamlessly;

the magnetic cores are equal in number to the fixed tubes and correspond to the fixed tubes one by one, one ends of the magnetic cores penetrate through the first through holes and are inserted into the corresponding fixed tubes, and the other ends of the magnetic cores are positioned outside the shell;

the tank body is cuboid, the opening of the tank body is upward, the size of the cross section of the tank body is the same as that of the second through hole, one end of the tank body penetrates through the second through hole, when one end of the tank body is in contact with the other side wall of the shell, the other end of the tank body is positioned outside the shell, and a gap between two adjacent fixed pipes in the fixed pipe at the bottommost layer is opposite to the tank body;

the connecting rod is positioned in the shell and arranged along the length direction of the shell, one end of the connecting rod is fixedly connected with one end of the groove body, and the other end of the connecting rod penetrates through the other side wall of the shell and is positioned outside the shell;

a linear guide rail extending in a longitudinal direction of the housing;

the sliding blocks are respectively and fixedly connected with the other ends of the magnetic cores and the other end of the connecting rod, and the sliding blocks are positioned on the linear guide rail;

the driving device is connected with the sliding block and is used for driving the sliding block to reciprocate on the linear guide rail;

and the two limiting plates are fixedly arranged at the top of one end and the other end of the groove body respectively.

2. The iron removal device of claim 1, wherein two ends of the material distribution plate are respectively positioned above two fixed tubes adjacent to the middle fixed tube in the topmost fixed tube.

3. The iron removal device of claim 2, further comprising:

the two baffles are symmetrically arranged relative to the axis of the shell, two tail ends of the material distribution plate are opposite to one baffle respectively and do not contact with the other baffle, one end of each baffle is fixedly connected with the top of the shell, the other end of each baffle extends to the lower portion of the material distribution plate and is positioned above the fixed pipe which is positioned in the fixed pipe at the topmost layer and adjacent to the fixed pipe in the middle, each baffle is rectangular, and two sides of each baffle, which are arranged at intervals in the length direction of the shell, are fixed to two side walls of the shell at intervals in the length direction of the shell respectively and are connected seamlessly.

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