Magnetic belt conveyor type magnetic particle separator

A magnetic belt conveyor type magnetic particle separator comprises a storage tank for storing cutting oil containing magnetic particles, an endless belt conveyor extending sidewise from the storage tank in an upwardly inclined direction, and a magnet disposed beneath the forward run of the belt conveyor to extend in the direction of running thereof. Magnetic particles contained in the cutting oil are attracted by the forces of the magnet to the upper surface of the forward run of the belt conveyor to be conveyed up to the forward run end thereof and separated therefrom at the forward run end for being discharged. The magnetic belt conveyor type magnetic particle separator further comprises scrapers mounted on the inner surface of the belt conveyor in a uniformly spaced-apart relation in the direction of running of the belt conveyor and moved in unison therewith over the upper surface of the magnet such as to scrape magnetic particles off the upper surface of the magnet, and projections projecting from the outer surface of the belt conveyor such as to catch masses of magnetic particles rolling over the outer surface of the belt conveyor.

BACKGROUND OF THE INVENTION 
This invention relates to magnetic belt conveyor type magnetic particle 
separators for separating magnetic particles from liquid containing such 
magnetic particles. 
The cutting oil or grinding oil having been used in factories generally 
contains indefinite numbers of magnetic particles. Such magnetic particles 
have to be removed by separation from the oil for the re-use thereof. As 
the separator for separating these magnetic particles, a magnetic belt 
conveyor type separator is well known in the art. The separator comprises 
an oil storage tank for storing cutting oil containing magnetic particles, 
a belt conveyor having one end portion extending in the oil storage tank 
and the other end portion extending therefrom in an upwardly inclined 
direction, and a magnet disposed beneath and arranged along the forward 
run of the belt conveyor. With this magnetic particle separator, 
indefinite numbers of magnetic particles contained in the cutting oil 
charged into the oil storage tank are attracted by the forces of the 
magnet to the upper surface of the forward run of the belt conveyor and 
conveyed up to the forward run end thereof above one side of the oil 
storage tank for being removed. 
The magnetic particles contained in the cutting oil have usually indefinite 
sizes and shapes and include fibrous or strip-like magnetic pieces or very 
fine particles. The fibrous or strip-like magnetic pieces tend to gather 
together and entangle one another to form spherical masses. Such masses of 
magnetic pieces, when attracted onto the upper surface of the belt 
conveyor, may roll together and fail to be conveyed to the forward run end 
of the belt conveyor. Also, very fine magnetic particles are likely to be 
introduced into a gap between the lower surface of the forward run of the 
belt conveyor and the upper surface of the magnet to be attracted to the 
magnet accumulated in the gap. The accumulation of magnetic particles in 
the gap causes wear of the belt conveyor and reduces the magnetic force of 
the magnets. 
SUMMARY OF THE INVENTION 
An object of the invention is to provide a magnetic belt conveyor type 
magnetic particle separator, which can effectively separate magnetic 
particles from liquid irrespective of the size or shape of the magnetic 
particles. Particularly, the invention seeks to provide a magnetic belt 
conveyor type magnetic particle separator, with which spherical masses of 
fibrous or strip-like magnetic pieces and very fine magnetic particles 
tending to be accumulated in the space between the belt conveyor and 
permanent magnet can be reliably discharged. 
To attain the above objective, the magnetic belt conveyor type magnetic 
particle separator according to the present invention comprises scrapers 
mounted on the inner surface of the belt conveyor in a spaced-apart 
relation in the direction of running of the belt conveyor and moved in 
unison therewith over the upper surface of the magnet such as to scrape 
magnetic particles off the magnet's upper surface, and projections 
projecting from the outer surface of the belt conveyor such as to catch 
masses of magnetic particles rolling over the belt conveyor outer surface.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
Now, a preferred embodiment of the invention will be described with 
reference to the accompanying drawings. 
As shown in FIGS. 1 and 2, a magnetic belt conveyor type magnetic particle 
separator includes an oil storage tank 1, a frame 2 and a belt conveyor 4. 
Cutting oil discharged from machine tools in a factory and containing 
magnetic particles is charged into the oil storage tank 1 in the direction 
of arrow A. One end portion of the frame 2 constitutes part of the side 
walls of the oil storage tank 1, and the other end portion of the frame 2 
extends in an upwardly inclined direction from the oil storage tank. The 
frame 2 is supported by a pair of legs 3. The belt conveyor 4 is made of 
an oil-resistant, wear-proof belt material and disposed along the frame 2. 
More particularly, the belt conveyor 4 has one end portion extending 
substantially horizontally along the portion of the frame 2 constituting 
the oil storage tank 1 and the other end portion extending in an upwardly 
inclined direction from the oil storage tank 1 along the other end portion 
of the frame. It is driven in the direction of arrow B. A number of 
scrapers 5 are mounted in a uniformly spaced-apart relation in the 
direction of its running on its inner side (back side). Each scraper 5 is 
a rod member of a rectangular cross section extending in the direction 
perpendicular to the direction of running of the belt conveyor 4. Its 
length is greater than the width of the belt conveyor, and its opposite 
end portions project from the belt conveyor. Each scraper 5 is secured by 
screws 6 to the inner side of the belt conveyor 4. The belt conveyor 4 
also has a number of protuberances, for instance spikes 7, projecting from 
its outer side (front side) and spaced apart at predetermined intervals in 
its running direction and transversal direction. In the instant 
embodiment, end portions of the screws 6 penetrate the belt conveyor 4 to 
the outer side and serve as the spikes 7. The spikes 7 are preferably 
arranged in a staggered fashion in the running direction of the belt 
conveyor 4. 
The belt conveyor 4 of the above construction is driven by chains 8 
provided on its opposite sides. More particularly, each end of the scraper 
5 projected from the belt conveyor 4 is coupled by a connecting bolt 9 and 
a connecting piece 10 to the associated chain 8, as shown in FIG. 5. The 
chains 8 are passed round driven sprockets 12 and inverted sprockets 11 
which are rotatably mounted on the frame 2, respectively and are disposed 
along the belt conveyor 4. The drive sprockets 12 are driven by a motor 13 
mounted on the frame 2. As the chains 8 are driven by the motor 13 in the 
direction of arrow B, the belt conveyor 4 is run in the same direction 
together with the chains 8 via the scraper 5. 
An assembly 15 of magnets is disposed under the forward run of the belt 
conveyor 4 such that it extends in the direction of running of the belt 
conveyor. The magnet assembly 15 includes, for instance, three permanent 
magnets 16 extending in the direction of running of the belt conveyor and 
arranged in a spaced-apart relation such that the width of the magnet 
assembly 15 is substantially the same as the width of the belt conveyor 4, 
and a case 17a and a lid 17b for accommodating the magnets 16. The case 
17a is secured by support members 32 to the frame 2. The lid 17b is made 
of, for instance, a stainless steel plate. Each lower surface of the 
scraper 5 is slightly spaced apart from the upper surface of the lid 17b 
and moved parallel to the upper surface of the lid along it. A left end 
portion of each permanent magnet 16 constitutes an attenuating magnetic 
force magnet 19 as shown in FIG. 6. A magnetic particle receiving member 
20 is connected to the left end of the magnet 15. A screw conveyor 21 is 
provided inside the receiving member 20. The screw conveyor 21 is rotated 
by a sprocket 20 meshing with one of the chains 8. A magnetic particle 
discharge outlet 23 is defined at one end of the receiving member 20. An 
oil return gutter 24 is disposed in the close proximity of the discharge 
outlet 23. The oil return gutter 24 communicates with the oil storage tank 
1. 
As shown in FIG. 2, a tensioning sprocket 25 and a magnet drum 26 are 
disposed adjacent to the drive sprockets 12 on the side of the backward 
run of the belt conveyor 4. The frame 2 has an opening formed at the end 
of its outwardly inclined portion, and a magnetic particle receptacle 27 
is disposed beneath the opening. The upper side of the upwardly inclined 
portion of the frame 2 is covered by a cover 28. Hopper plates 29 are 
mounted on side wall portions of the frame 2 constituting the oil storage 
tank 1. The hopper plates 29 have respective filters 30, for instance made 
of sponge, and depending from their lower edges. 
The operation of the magnetic belt conveyor type magnetic particle 
separator having the above construction will now be described. 
Cutting oil supplied from machine tools is discharged into the oil storage 
tank 1 in the direction of arrow A. Magnetic particles contained in the 
cutting oil fall and are collected on the upper surface of the forward run 
of the belt conveyor 4. At this time, the magnetic particles are guided by 
the hopper plates 29 onto the upper surface of the belt conveyor 4. 
Magnetic particles approaching the upper surface of the belt conveyor 4 
are attracted thereto by the magnetic forces of the magnet assembly 15. As 
the belt conveyor 4 proceeds in the direction of arrow B, the magnetic 
particles attracted to the upper surface of the belt conveyor 4 are 
carried thereby up to the forward run end thereof. At the forward run end 
of the belt conveyor, the magnetic particles are separated therefrom and 
fall into the magnetic particle receptacle 27 provided below. Magnetic 
particles remaining stuck to the belt conveyor 4 due to the viscosity of 
the cutting oil reach the magnet drum 6 where they are attracted to the 
side thereof and removed. 
Fibrous or strip-like magnetic pieces entangle one another into spherical 
masses before they are supplied together with oil to the oil storage tank 
1. If the belt conveyor has a flat top surface, these spherical masses of 
magnetic pieces will roll over the belt conveyor and sometimes fail to be 
conveyed to the forward run end of the conveyor. Since the belt conveyor 4 
according to the invention has the spikes 7 projecting from its upper 
surface, the masses of magnetic pieces are caught on the spikes 7. Thus, 
these masses of the magnetic pieces are reliably conveyed up to the 
forward run end of the belt conveyor 4 to be separated therefrom at that 
end and fall into the receptacle 27. 
Very fine magnetic particles are liable to escape sidewise of the conveyor 
4 through the gap between the lower edge of each hopper plate 29 and the 
upper surface of the conveyor 4. However, the filters 30 depending to 
close the gaps block the magnetic particles. Magnetic particles that may 
clear even the filters 30 intrude into the gap between the lid 17b of the 
magnet assembly 15 and the lower surface of the forward run of the belt 
conveyor 4 and accumulate in this gap. However, the scrapers 5 are mounted 
on the inner surface of the belt conveyor 4 and moved in unison with the 
belt conveyor over and along the lid 17b. Therefore, the magnetic 
particles having accumulated into the aforementioned gap are scraped off 
by the scrapers 5 and carried along up to the left hand end of the magnet 
assembly 15. Since the left hand end portions of the permanent magnets 16 
constitute attenuating magnetic force magnets 19, the magnetic particles 
carried thereto experience attenuating magnetic force of the magnet 16 to 
eventually fall from the end thereof into the receiving member 20. 
The magnetic particles tending to accumulate in the gap between the lower 
surface of the belt conveyor 4 and the magnet assembly 15 are most 
effectively removed if the scrapers 5 are mounted such that their lower 
ends are in frictional contact with the upper surface of the lid 17b. In 
the instant embodiment, however, the scrapers 5 are mounted such that 
their lower end is slightly spaced apart from the lid 17b by taking the 
wear of the scrapers 5 and lid 17b into considerations. 
Since the screw conveyor 21 is provided inside the receiving plate 20, the 
magnetic particles having fallen into the receiving member 20 are conveyed 
by the screw conveyor 21 in the direction of arrow C to be discharged from 
the discharge outlet 23. Also, slight cutting oil having been transferred 
together with magnetic particles to the receiving member 20 is returned 
through the return gutter 24 to the oil storage tank 1. 
It is to be appreciated that with this embodiment whatever magnetic 
particles can be separated from the cutting oil irrespective of their size 
or shape. 
In the above embodiment, the screws 6 which secure the scrapers 5 to the 
belt conveyor 4 also serve as the spikes 7. Thus, the number of component 
parts is reduced to simplify the assembly and construction. However, it is 
of course possible to use spikes 7 and screws 6 as separate parts. 
FIG. 8 shows a modification of the above embodiment. In this modification, 
other scrapers 80 are provided on the outer side of the belt conveyor 4 as 
well. The conveyor 4 is thus sandwiched between these scrapers 80 and the 
aforementioned scrapers 5 provided on the inner side of the belt conveyor 
4. Here, the spikes 7 may again be constituted by the screws 6 securing 
the scrapers 5 and 80 to the belt conveyor 4 in the sandwiching relation 
thereto. The provision of the scrapers 80 on the upper surface of the belt 
conveyor 4 has an effect of still bettering the magnetic particle 
transport performance of the belt conveyor 4. 
While the above embodiment of the invention has concerned with the 
separation of magnetic particles contained in the cutting oil, it is by no 
means limitative, and the invention is also applicable to various other 
fields such as the separation of minerals in the mining field or the 
separation of magnetic particles contained in a liquid material in 
production fields dealing with liquid materials.