CN205042602U - Semi -automatic magnetic filter - Google Patents

Abstract

The utility model relates to a foul solution processing technique field discloses a semi -automatic magnetic filter, including the barrel, the barrel has water inlet and delivery port, and still including the magnetic core that is located the barrel, the magnetic core activity is installed in the barrel, the outside sleeve of magnetic core is located to the cover, and the sleeve is fixed in lid or barrel, and the sleeve is non magnetic, pending foul solutions such as coolant liquid pass through the barrel that the water inlet got into semi -automatic magnetic filter, and the magnetic core in the barrel passes through magnetism suction and adsorbs the magnetism debris on the sleeve, and the coolant liquid of filtering magnetism debris is through the delivery port semi -automatic magnetic filter that flows, pull out the magnetic core, the magnetism debris drop from the sleeve promptly, along with the coolant liquid through the delivery port semi -automatic magnetic filter that discharges, the utility model discloses simple structure, the blowdown is convenient, does not need additionally to add auxiliary assembly and carries out the blowdown, reduces foul solution treatment cost.

Description

A kind of semi-automatic magnetic filter

Technical field

The utility model relates to soiling solution processing technology field, particularly relates to a kind of semi-automatic magnetic filter.

Background technology

Process of metal working needs to consume a large amount of water base cooling fluid, and in the process of metal cutting process, often can produce the foreign material such as some thin chips, metal dust and emery wheel powder, and these foreign material are mostly mixed in cooling fluid.

The easy blocking pipeline of these type of foreign material, damages the sealing of pump; Foreign material are deposited in bottom oil sump, coalescent with organic matter, form the beds of precipitation that one deck has a large amount of pore, and for microbial reproduction provides advantage, the breeding of a large amount of microorganism can cause cooling fluid smelly rotten, causes cooling fluid not use afterwards; In addition, the metal dust in cooling fluid has very high chemism, and some composition in cooling fluid can be made to lose efficacy.

Foreign material (as chip, metal dust etc.) in cooling fluid also can reduce cutting-tool's used life greatly, because when machining, foreign material will enter on the interface of cutter knife face and work piece contact zone, produce strong friction therefrom, cutting temperature is increased, and tool life is reduced greatly, make machined surface quality be deteriorated simultaneously.

In order to improve cutter life and reliability thereof, improving part crudy, purified treatment need be carried out to cooling fluid.

Summary of the invention

In order to overcome the shortcoming and defect existed in prior art, the purpose of this utility model is to provide a kind of semi-automatic magnetic filter, and structure is simple, and blowdown is convenient, does not need additional auxiliary equipment to carry out blowdown, reduces soiling solution processing cost.

For achieving the above object, the semi-automatic magnetic filter of one of the present utility model, comprises cylindrical shell, and described cylindrical shell has water inlet and delivery port, also comprises the magnetic core being positioned at described cylindrical shell, and described magnetic core is movably arranged in described cylindrical shell; Be sheathed on the sleeve of described magnetic core outside, described sleeve is non-magnetic member.

Wherein, be provided with dividing plate in described cylindrical shell, described dividing plate both sides are equipped with described magnetic core.

Wherein, described semi-automatic magnetic filter also comprises the lid being installed on described cylindrical shell, and one end of described magnetic core is connected to described lid; Described dividing plate comprises the first dividing plate and second partition, and described first dividing plate and described second partition interval are arranged; Between described first dividing plate and described lid, there is gap, between described first dividing plate and the diapire of described cylindrical shell, there is gap; Between the diapire of described second partition and described cylindrical shell, there is gap, between described second partition and described lid, not there is gap.

Wherein, described first dividing plate forms towards described lid extension from the diapire of described cylindrical shell; Described second partition forms towards the extension of the diapire of described cylindrical shell from described lid.

Wherein, described first dividing plate and described second partition all extend from the sidewall of described cylindrical shell form towards the sidewalls relative with above-mentioned sidewall.

Wherein: described lid has through hole, and described sleeve is fixed on described lid and is communicated with described through hole; Described magnetic core is movably arranged in described sleeve by described through hole.

Wherein, described sleeve is fixed on described cylindrical shell by bracing frame; Described magnetic core is movably arranged in described sleeve by described lid.

Wherein, described magnetic core is rare-earth magnet.

Wherein, described magnetic core is ndfeb magnet.

Wherein, the material of described sleeve is stainless steel.

The beneficial effects of the utility model: the soiling solutions such as pending cooling fluid enter the cylindrical shell of semi-automatic magnetic filter by water inlet, magnetic foreign material are adsorbed on sleeve by magnetic attraction by the magnetic core in cylindrical shell, and the cooling fluid of filtering magnetic foreign material flows out semi-automatic magnetic filter through delivery port; Pulled out by magnetic core, namely magnetic foreign material come off from sleeve, along with cooling fluid discharges semi-automatic magnetic filter through delivery port; the utility model structure is simple, and blowdown is convenient, does not need additional auxiliary equipment to carry out blowdown; and without the need to shutting down manual cleaning, reduce soiling solution processing cost.

Accompanying drawing explanation

Fig. 1 is perspective view of the present utility model;

Fig. 2 is decomposition texture schematic diagram of the present utility model;

Fig. 3 is the perspective view of cylindrical shell of the present utility model;

Fig. 4 is the sectional view along A-A direction in Fig. 1;

Fig. 5 is the decomposition texture schematic diagram at another visual angle of the present utility model;

Fig. 6 is the sectional view of the second embodiment of the present utility model.

Reference numeral comprises:

1-cylindrical shell, 10-water inlet, 100-water inlet pipe

11-delivery port, 110-outlet pipe, 12-diapire

13-annular sidewall, 14-opening, 15-bracing frame

16-the first dividing plate 17-second partition 2-lid

20-short slot, 21-through hole, 3-magnetic core

4-sleeve, 5-fixed head, 50-stator

51-pilot hole, 6-fixture, 60-assembly parts

61-locking part, 62-Assembly rail, 63-threaded rod

7-capture block.

Detailed description of the invention

For the ease of the understanding of those skilled in the art, be further described below in conjunction with embodiment and accompanying drawing 1 ~ 6 pair of the utility model, the content that embodiment is mentioned is not to restriction of the present utility model.

Refer to shown in Fig. 1, Fig. 2 and Fig. 3, the semi-automatic magnetic filter of one of the present utility model, comprise cylindrical shell 1, be installed on the lid 2 on the top of described cylindrical shell 1, described cylindrical shell 1 has water inlet 10 and delivery port 11, is equiped with magnetic core 3 in described cylindrical shell 1, and it is inner that described magnetic core 3 is movably arranged on described cylindrical shell 1 by described lid 2, described magnetic core 3 outer cover is provided with sleeve 4, and described sleeve 4 is non-magnetic member.

Described cylindrical shell 1 is roughly in hollow circular cylinder shape, and certainly, those skilled in the art also can be set to other shapes according to specific needs, such as other shapes such as rectangular-shaped, triangular prism shape.

Described cylindrical shell 1 comprises diapire 12, annular sidewall 13 and opening 14, and one end of described annular sidewall 13 is connected to described diapire 12, and the other end of described annular sidewall 13 forms described opening 14, and described opening 14 is oppositely arranged with described diapire 12.Described annular sidewall 13 offers water inlet 10 and delivery port 11, in the present embodiment, it is inner that described water inlet 10 is communicated with described cylindrical shell 1 by water inlet pipe 100, and it is inner that described delivery port 11 is communicated with described cylindrical shell 1 by outlet pipe 110.

Described water inlet pipe 100 be positioned at described annular sidewall 13 upper end and near described opening 14, described outlet pipe 110 be positioned at described annular sidewall 13 lower end and near described diapire 12, described water inlet pipe 100 and described outlet pipe 110 lay respectively at position respect to one another, described annular sidewall 13 both sides, so arrange and ensure can not collide when installing other parts on described water inlet pipe 100 and described outlet pipe 110.

The upper end of described annular sidewall 13 is evenly provided with multiple fixed head 5 around described opening 14, and described fixed head 5 is for being mounted with part 6 with fixing described lid 2.Fixed head 5 described in each comprises two stators 50, and stator 50 described in each has pilot hole 51 away from one end of described annular sidewall 13.

Described fixture 6 comprises assembly parts 60 and locking part 61, described assembly parts 60 are generally t-shaped, the threaded rod 63 that described assembly parts 60 comprise two Assembly rails 62 and vertically extend between Assembly rail described in two 62, Assembly rail 62 described in two is arranged in described pilot hole 51 respectively, and described locking part 61 is coordinated with described threaded rod 63 by screwed hole (not shown) provided thereon.

Refer to shown in Fig. 2 and Fig. 5, described lid 2 is roughly in the form of annular discs, and described lid 2 is evenly provided with multiple short slot 20, and described short slot 20 forms towards center extension from the edge of described lid 2.When described lid 2 is fixed on described opening 14 by needs, described assembly parts 60 are rotated up, described threaded rod 63 is made to be arranged in described short slot 20, again described locking part 61 is assembled to described threaded rod 63, by the threaded engagement between described threaded rod 63 and described locking part 61, described lid 2 is pressed abd fixed on the top of described cylindrical shell 1.

Described lid 2 has multiple through hole 21, described sleeve 4 is fixed on the lower end of described lid 2 by the mode of welding and is communicated with described through hole 21, described sleeve 4 is positioned at described cylindrical shell 1, described magnetic core 3 is movably arranged in described sleeve 4 by described through hole 21, conveniently described magnetic core 3 taking-up and put into, multiple described magnetic core 3 can be connected on same crawl block 7.

Refer to shown in Fig. 6, certainly, described sleeve 4 also can be fixed on described cylindrical shell 1, such as, be provided with multiple bracing frame 15 in described cylindrical shell 1, described sleeve 4 is fixed on support frame as described above 15 and then is installed in described cylindrical shell 1, now, described magnetic core 3 also can directly be fixed on described lid 2, and described magnetic core 3 is movably arranged in described sleeve 4 by described lid 2.

Refer to shown in Fig. 2, Fig. 3, Fig. 4 and Fig. 5, in described cylindrical shell 1, dividing plate is installed, described dividing plate both sides are equipped with described magnetic core 3, described dividing plate is for stopping the cutting fluid entered in described cylindrical shell 1, in order to reduce the flow velocity of cutting fluid, make cutting fluid stop the longer time in described cylindrical shell 1, and then make the magnetic foreign material in described magnetic core 3 absorption cutting fluid as much as possible.

Preferably, described dividing plate comprises the first dividing plate 16 and second partition 17, and described first dividing plate 16 is spaced with described second partition 17 and be arranged in parallel, and described first dividing plate 16 forms towards described lid 2 extension from described diapire 12; Have gap between described first dividing plate 16 and the diapire 12 of described cylindrical shell 1, the magnetic foreign material that follow-up described magnetic core 3 adsorbs flow through described gap and then discharge described cylindrical shell 1 by described outlet pipe 110.Also there is gap between described first dividing plate 16 and described lid 2, ensure that the cutting fluid in described cylindrical shell 1 can by described Clearance Flow.

Certainly, described first dividing plate 16 also can form towards described diapire 12 extension from described lid 2, or described first dividing plate 16 forms towards opposite side extension on the other side from the side of described annular sidewall 13.

Described second partition 17 forms towards described diapire 12 extension from described lid 2, for being sealed and matched, not there is gap between described second partition 17 and described lid 2, between described second partition 17 and described diapire 12, there is gap, setting like this, ensure that the cutting fluid entered in described cylindrical shell 1 can only by described Clearance Flow, ensure that cutting fluid lowers flow velocity, make described magnetic core 3 have sufficiently long time of contact with cutting fluid.Certainly, described second partition 17 also can form towards opposite side extension on the other side from the side of described annular sidewall 13.

The operation principle of the semi-automatic magnetic filter of the utility model is as follows:

Refer to shown in Fig. 1, Fig. 2 and Fig. 4, the soiling solutions such as pending cutting fluid are entered in described cylindrical shell 1 by described water inlet pipe 100, the cutting fluid entered in described cylindrical shell 1 first flows through the gap between described second partition 17 and described diapire 12, flow through the gap between described first dividing plate 16 and described diapire 12, described lid 2 again, described cylindrical shell 1 is discharged finally by described outlet pipe 110, in the process, magnetic foreign material in cutting fluid are adsorbed on the superficies of described sleeve 4 by described magnetic core 3 by magnetic attraction, thus play filtering effect.

The magnetic attraction of described magnetic core 3 is larger, and it is more thorough that the magnetic foreign material in cutting fluid will filter, and in order to make described magnetic core 3 have larger suction, described magnetic core 3 adopts rare-earth magnet, and preferably, described magnetic core 3 is ndfeb magnet.The absorption affinity of rare-earth magnet is ten times of general magnetic material, have moment liquid flow impact or high flow condition under, adsorb the ability of micron-sized magnetic foreign material, and under high speed large impact, the magnetic foreign material in cutting fluid can be adsorbed.

When needing the magnetic foreign material removing described sleeve 4 superficies, outlet pipe 110 is connected to refuse collecting place, user picks up described crawl block 7 and then described magnetic core 3 is pulled out described sleeve 4, because described sleeve 4 is nonmagnetic substance, such as plastic cement, carbon fiber, in order to extend the service life of described sleeve 4, the material of described sleeve 4 adopts stainless steel, after described magnetic core 3 pulls out, described sleeve 4 loses magnetism, magnetic foreign material from Automatic-falling described sleeve 4, then are discharged described cylindrical shell 1 with cutting fluid by described outlet pipe 110 and are flow to refuse collecting place.

Certainly; those skilled in the art also can shut down by described semi-automatic magnetic filter; described lid 2 is separated with described cylindrical shell 1; described lid 2 is together taken out together with described magnetic core 3 and is placed on precalculated position; then described magnetic core 3 is pulled out; described sleeve 4 loses magnetism, and magnetic foreign material are from Automatic-falling described sleeve 4 to precalculated position.

The utility model structure is simple, and blowdown is convenient, does not need additional auxiliary equipment to carry out blowdown, and without the need to shutting down manual cleaning, greatly reduces the processing cost of the soiling solutions such as cutting fluid.

Known the utility model is have above-described good characteristic in sum, is made it in use, promotes in conventional art the usefulness that do not have and has practicality, becoming the product that has practical value.

Above content is only preferred embodiment of the present utility model, for those of ordinary skill in the art, according to thought of the present utility model, all will change in specific embodiments and applications, this description should not be construed as restriction of the present utility model.

Claims (10)

1. a semi-automatic magnetic filter, comprises cylindrical shell, and described cylindrical shell has water inlet and delivery port, it is characterized in that: also comprise the magnetic core being positioned at described cylindrical shell, and described magnetic core is movably arranged in described cylindrical shell; Be sheathed on the sleeve of described magnetic core outside, described sleeve is non-magnetic member.

2. semi-automatic magnetic filter according to claim 1, is characterized in that: be provided with dividing plate in described cylindrical shell, described dividing plate both sides are equipped with described magnetic core.

3. semi-automatic magnetic filter according to claim 2, is characterized in that: described semi-automatic magnetic filter also comprises the lid being installed on described cylindrical shell, and one end of described magnetic core is connected to described lid; Described dividing plate comprises the first dividing plate and second partition, and described first dividing plate and described second partition interval are arranged; Between described first dividing plate and described lid, there is gap, between described first dividing plate and the diapire of described cylindrical shell, there is gap; Between the diapire of described second partition and described cylindrical shell, there is gap, between described second partition and described lid, not there is gap.

4. semi-automatic magnetic filter according to claim 3, is characterized in that: described first dividing plate forms towards described lid extension from the diapire of described cylindrical shell; Described second partition forms towards the extension of the diapire of described cylindrical shell from described lid.

5. semi-automatic magnetic filter according to claim 3, is characterized in that: described first dividing plate and described second partition all extend from the sidewall of described cylindrical shell form towards the sidewall relative with above-mentioned sidewall.

6. semi-automatic magnetic filter according to claim 3, is characterized in that: described lid has through hole, described sleeve is fixed on described lid and is communicated with described through hole; Described magnetic core is movably arranged in described sleeve by described through hole.

7. semi-automatic magnetic filter according to claim 3, is characterized in that: described sleeve is fixed on described cylindrical shell by bracing frame; Described magnetic core is movably arranged in described sleeve by described lid.

8. semi-automatic magnetic filter according to claim 1, is characterized in that: described magnetic core is rare-earth magnet.

9. semi-automatic magnetic filter according to claim 8, is characterized in that: described magnetic core is ndfeb magnet.

10. semi-automatic magnetic filter according to claim 1, is characterized in that: the material of described sleeve is stainless steel.