CN115070034B

CN115070034B - Anti-adhesion magnetic powder core sintering device

Info

Publication number: CN115070034B
Application number: CN202210744075.5A
Authority: CN
Inventors: 缪建兵
Original assignee: Anhui Zhongma Magnetic Energy Technology Co ltd
Current assignee: Anhui Zhongma Magnetic Energy Technology Co ltd
Priority date: 2022-06-27
Filing date: 2022-06-27
Publication date: 2023-11-03
Anticipated expiration: 2042-06-27
Also published as: CN115070034A

Abstract

The invention relates to an anti-adhesion magnetic powder core sintering device, which comprises a sintering furnace, wherein one side of the sintering furnace is provided with a supporting plate, the top surface of the supporting plate is provided with a limit groove, the inside of the limit groove is provided with a sliding seat in a sliding manner, and the top of the sliding seat is provided with a taking mechanism for taking out a supporting frame filled with a magnetic powder core; the extension end of the hydraulic cylinder is extended, so that the taking rod extends into the sintering furnace, the external moving vehicle provided with the support frame is clamped by the spring lock catch, the magnetic powder core is conveniently taken out from the sintering furnace by the spring lock catch, and meanwhile, the damage of waste heat in the sintering furnace to an operator is reduced; when the take-out rod resets, the rotating plate is driven to rotate through the transmission rod, so that the push plate provides thrust for the magnetic powder core, the magnetic powder core is separated from the support frame, and the magnetic powder core is prevented from being adhered to the support frame.

Description

Anti-adhesion magnetic powder core sintering device

Technical Field

The invention relates to the technical field of sintering equipment, in particular to an anti-adhesion magnetic powder core sintering device.

Background

According to the modified neodymium iron boron magnet forming and sintering device disclosed in the patent document with the publication number of CN215770846U, the cooling speed can be fast increased through the heat dissipation assembly, the cooling speed is extremely fast, the sintering of the next round can be continued without long-time stopping, and the working efficiency is high; but the device is with the back of magnetic powder core sintering, inconvenient when taking out the magnetic powder core, and the inside waste heat of fritting furnace causes the injury to the operator easily, produces the adhesion between the easy and support frame of magnetic powder core after the sintering simultaneously, inconvenient taking off the magnetic powder core, has reduced the efficiency of magnetic powder core processing.

Disclosure of Invention

The technical problem solved by the scheme is as follows:

(1) How to extend the extending end of the hydraulic cylinder through the arrangement of the taking mechanism, so that the taking rod extends into the sintering furnace, the external moving vehicle provided with the supporting frame is clamped by the spring lock catch, the magnetic powder core is conveniently taken out from the sintering furnace by the spring lock catch, the taking speed of the magnetic powder core is accelerated, and meanwhile, the damage of waste heat in the sintering furnace to an operator is reduced;

(2) How is through setting up anti-adhesion unit, when the pole of taking resets, drives the rotor plate through the transfer line and takes place to rotate for the rotor plate pulling movable plate slides, thereby promotes the push pedal to remove towards the magnetic powder core direction on the support frame, and the push pedal provides thrust to the magnetic powder core, makes magnetic powder core and support frame break away from, prevents magnetic powder core and support frame adhesion, conveniently takes off magnetic powder core.

The aim of the invention can be achieved by the following technical scheme: the anti-adhesion magnetic powder core sintering device comprises a sintering furnace, wherein one side of the sintering furnace is provided with a supporting plate, the top surface of the supporting plate is provided with a limiting groove, the inside of the limiting groove is provided with a sliding seat in a sliding manner, and the top of the sliding seat is provided with a taking mechanism for taking out a supporting frame of a magnetic powder core in the sintering furnace; when the magnetic powder core needs to be placed into the sintering furnace for sintering, an operator pulls the sliding seat to slide in the limiting groove to the end far away from the sintering furnace, the sealing door is opened, the magnetic powder core is moved into the sintering furnace through the external moving vehicle, the blocking of the sliding seat to the external moving vehicle is avoided, when the sintered magnetic powder core is taken, the sliding seat is manually pushed to slide in the limiting groove to the end close to the sintering furnace, and in the process of taking the magnetic powder core, the sliding seat is prevented from sliding due to the fact that the limiting groove limits the sliding seat;

the taking mechanism comprises a first rotating rod and a second rotating rod which are hinged to a sliding seat, one ends of the first rotating rod and the second rotating rod are hinged to the taking rod together, a spring lock catch is fixedly arranged at one end of the taking rod, which is close to the sintering furnace, the spring lock catch is of the prior art, the model is G-079, a hydraulic cylinder is further rotationally arranged on the sliding seat, a fixing pin is fixedly connected to the extending end of the hydraulic cylinder, the middle part of the second rotating rod is hinged to the fixing pin, and a transmission mechanism is arranged at one end of the sliding seat, which is close to the sintering furnace; after the sintering of the magnetic powder core in the sintering furnace is completed, after the sealing door is opened, the external moving vehicle stretches into the internal supporting frame of the sintering furnace, the sliding seat is pushed to be close to the sintering furnace, the stretching end of the hydraulic cylinder stretches out, the taking rod stretches into the sintering furnace under the action of the first rotating rod and the second rotating rod, the external moving vehicle provided with the supporting frame is clamped by the spring lock catch, the stretching end of the hydraulic cylinder contracts, the magnetic powder core is taken out from the sintering furnace by the spring lock catch, the taking speed of the magnetic powder core is accelerated, and meanwhile damage to an operator caused by waste heat in the sintering furnace is reduced.

The invention further technically improves that: the input port of the sintering furnace is hinged with a sealing door.

The invention further technically improves that: the transmission mechanism comprises a fixing frame fixedly connected with a sliding seat, two parallel guide rails are fixedly arranged at the bottom of the fixing frame, an anti-adhesion unit for pushing a magnetic powder core is slidably arranged between the two guide rails, a rotating plate is rotatably arranged on the sliding seat through a pin shaft, second sliding grooves are formed in two sides of the rotating plate, a transmission rod is hinged to the middle of the first rotating rod, a second deflector rod is fixedly connected to one end of the transmission rod, and the second deflector rod is movably connected with one of the second sliding grooves.

The invention further technically improves that: the anti-adhesion unit comprises a movable plate arranged between two guide rails in a sliding manner, a vertically arranged push plate is fixedly arranged at the bottom of the movable plate, a rotating seat is fixedly arranged at one end, far away from the push plate, of the movable plate, a first deflector rod is fixedly connected to the bottom of the rotating seat, and the first deflector rod is movably connected with the other second chute; when the take pole resets, first dwang takes place to rotate, drives the pivoted board through the transfer line and rotates for the pivoted seat pulling movable plate takes place to slide under the spacing condition of two guide rails, thereby promotes the push pedal and removes towards the magnetic powder core direction on the support frame, and the push pedal provides thrust to the magnetic powder core, makes magnetic powder core and support frame break away from, prevents that magnetic powder core and support frame adhesion, conveniently takes off magnetic powder core.

The invention further technically improves that: the two sides of the movable plate are symmetrically provided with sliding blocks, and the movable plate is respectively connected with two corresponding guide rails in a sliding manner through the two sliding blocks.

The invention further technically improves that: the bottom of the sintering furnace is fixedly provided with two bases.

Compared with the prior art, the invention has the beneficial effects that:

when the magnetic powder core sintering device is used, after the sealing door is opened after the sintering of the magnetic powder core in the sintering furnace is completed, the external moving vehicle is stretched into the internal supporting frame of the sintering furnace, the sliding seat is pushed to be close to the sintering furnace, the stretching ends of the hydraulic cylinders stretch to enable the taking rod to stretch into the sintering furnace under the action of the first rotating rod and the second rotating rod, the external moving vehicle provided with the supporting frame is clamped by the aid of the spring lock catch, the stretching ends of the hydraulic cylinders shrink, the magnetic powder core is conveniently taken out from the sintering furnace by the aid of the spring lock catch, the taking speed of the magnetic powder core is accelerated, and meanwhile damage to operators caused by waste heat in the sintering furnace is reduced.

When the magnetic powder core taking device is used, when the taking rod is reset, the first rotating rod rotates, the rotating plate is driven to rotate through the transmission rod, so that the rotating seat pulls the moving plate to slide under the limiting condition of the two guide rails, the pushing plate is pushed to move towards the magnetic powder core on the supporting frame, the pushing plate provides pushing force for the magnetic powder core, the magnetic powder core is separated from the supporting frame, the magnetic powder core is prevented from being adhered to the supporting frame, and the magnetic powder core is convenient to take down.

Drawings

The present invention is further described below with reference to the accompanying drawings for the convenience of understanding by those skilled in the art.

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a schematic perspective view of the structure of the sintering furnace of the invention;

FIG. 3 is a schematic view of a picking mechanism according to the present invention;

FIG. 4 is a schematic diagram of a picking mechanism according to a second embodiment of the present invention;

FIG. 5 is a schematic diagram of the transmission mechanism of the present invention;

fig. 6 is a schematic perspective view of the structure of the anti-blocking unit of the present invention.

In the figure: 1. sealing the door; 2. a picking mechanism; 3. a sliding seat; 4. a limit groove; 5. a support plate; 6. a base; 7. a sintering furnace; 201. a transmission mechanism; 202. a spring lock catch; 203. taking the rod; 204. a second rotating lever; 205. a hydraulic cylinder; 206. a first rotating lever; 2011. a moving plate; 2012. a fixing frame; 2013. a guide rail; 2014. a rotating plate; 2015. a pin shaft; 2016. a transmission rod; 2017. a rotating seat; 2018. a push plate; 2019. a sliding block.

Detailed Description

The technical solutions of the present invention will be clearly and completely described in connection with the embodiments, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1 and 2, an anti-adhesion magnetic powder core sintering device comprises a sintering furnace 7, wherein two bases 6 are fixedly arranged at the bottom of the sintering furnace 7, a sealing door 1 is hinged at an input port of the sintering furnace 7, a supporting plate 5 is arranged at one side of the sintering furnace 7, a limit groove 4 is formed in the top surface of the supporting plate 5, and a sliding seat 3 is slidably arranged in the limit groove 4; when needing to place the magnetic powder core and getting into sintering furnace 7 and sintering, the operator pulls sliding seat 3 and slides to the one end of keeping away from sintering furnace 7 in spacing groove 4, open sealing door 1, rethread outside locomotive removes the magnetic powder core to sintering furnace 7 in, avoid sliding seat 3 to cause the hindrance to outside locomotive, when taking the magnetic powder core that the sintering has been accomplished, slide to the one end that is close to sintering furnace 7 in spacing groove 4 through artifical promotion sliding seat 3, in the in-process of taking the magnetic powder core, because spacing groove 4 carries out spacingly to sliding seat 3, prevent sliding seat 3 slip, the top of sliding seat 3 is provided with the mechanism 2 of taking that is used for taking out the support frame of the magnetic powder core that is equipped with in sintering furnace 7.

Referring to fig. 3 and 4, the above-mentioned taking mechanism 2 includes a first rotating rod 206 and a second rotating rod 204 hinged on a sliding seat 3, one ends of the first rotating rod 206 and the second rotating rod 204 are hinged with a taking rod 203 together, one end of the taking rod 203 close to the sintering furnace 7 is fixedly provided with a spring lock 202, the spring lock 202 is in the prior art, and the model is G-079, the sliding seat 3 is further rotatably provided with a hydraulic cylinder 205, the extending end of the hydraulic cylinder 205 is connected with a fixing pin, the middle part of the second rotating rod 204 is hinged with the fixing pin, and one end of the sliding seat 3 close to the sintering furnace 7 is provided with a transmission mechanism 201; after the sintering of the magnetic powder core in the sintering furnace 7 is completed, after the sealing door 1 is opened, the external moving vehicle stretches into the sintering furnace 7 to be provided with the supporting frame, the sliding seat 3 is pushed to be close to the sintering furnace 7, the stretching end of the hydraulic cylinder 205 stretches out, the taking rod 203 stretches into the sintering furnace 7 under the action of the first rotating rod 206 and the second rotating rod 204, the external moving vehicle provided with the supporting frame is clamped by the spring lock 202, the stretching end of the hydraulic cylinder 205 contracts, the magnetic powder core is conveniently taken out from the sintering furnace 7 by the spring lock 202, and meanwhile, the damage to an operator caused by waste heat in the sintering furnace 7 is reduced.

Referring to fig. 5, the transmission mechanism 201 includes a fixing frame 2012 fixedly connected to the sliding seat 3, and two parallel guide rails 2013 are fixedly installed at the bottom of the fixing frame 2012; the anti-adhesion unit is limited through the two guide rails 2013, the situation that the anti-adhesion unit is separated from the guide rails 2013 is prevented, normal use of the anti-adhesion unit is guaranteed, the anti-adhesion unit for pushing the magnetic powder core is arranged between the two guide rails 2013 in a sliding mode, the rotating plate 2014 is arranged on the sliding seat 3 in a rotating mode through the pin shaft 2015, second sliding grooves are formed in two sides of the rotating plate 2014, the middle portion of the first rotating rod 206 is hinged to the transmission rod 2016, one end of the transmission rod 2016 is fixedly connected with the second shifting rod, and the second shifting rod is movably connected with one of the second sliding grooves.

Referring to fig. 6, the anti-adhesion unit includes a moving plate 2011, two sides of the moving plate 2011 are symmetrically provided with sliding blocks 2019, the moving plate 2011 is respectively and slidably connected with two corresponding guide rails 2013 through two sliding blocks 2019, a vertically arranged push plate 2018 is fixedly installed at the bottom of the moving plate 2011, a rotating seat 2017 is fixedly installed at one end of the moving plate 2011 far away from the push plate 2018, a first deflector rod is fixedly connected at the bottom of the rotating seat 2017, and the first deflector rod is movably connected with another second chute; when the taking rod 203 resets, the first rotating rod 206 rotates, the rotating plate 2014 is driven to rotate by the transmission rod 2016, so that the rotating seat 2017 pulls the moving plate 2011 to slide under the limiting condition of the two guide rails 2013, thereby pushing the push plate 2018 to move towards the magnetic powder core on the support frame, the push plate 2018 provides thrust for the magnetic powder core, so that the magnetic powder core is separated from the support frame, the magnetic powder core is prevented from being adhered to the support frame, and the magnetic powder core is convenient to take down.

Working principle: when the magnetic powder core sintering device is used, firstly, when the magnetic powder core needs to be placed into the sintering furnace 7 for sintering, an operator pulls the sliding seat 3 to slide in the limiting groove 4 to one end far away from the sintering furnace 7, the sealing door 1 is opened, then the magnetic powder core is moved into the sintering furnace 7 through the external moving vehicle, the sliding seat 3 is prevented from obstructing the external moving vehicle, when the sintered magnetic powder core is taken, the sliding seat 3 is manually pushed to slide in the limiting groove 4 to one end close to the sintering furnace 7, and in the process of taking the magnetic powder core, the sliding seat 3 is limited by the limiting groove 4, so that the sliding seat 3 is prevented from sliding; after the sintering of the magnetic powder core in the sintering furnace 7 is completed, the sealing door 1 is opened, the external moving vehicle is stretched into the sintering furnace 7 to be provided with the supporting frame, the sliding seat 3 is pushed to be close to the sintering furnace 7, the stretching ends of the hydraulic cylinders 205 are stretched, the taking rod 203 stretches into the sintering furnace 7 under the action of the first rotating rod 206 and the second rotating rod 204, the external moving vehicle provided with the supporting frame is clamped by the spring lock 202, the stretching ends of the hydraulic cylinders 205 are contracted, the magnetic powder core is conveniently taken out from the sintering furnace 7 by the spring lock 202, and meanwhile, the damage to an operator caused by waste heat in the sintering furnace 7 is reduced; when the taking rod 203 resets, the first rotating rod 206 rotates, the rotating plate 2014 is driven to rotate by the transmission rod 2016, so that the rotating seat 2017 pulls the moving plate 2011 to slide under the limiting condition of the two guide rails 2013, thereby pushing the push plate 2018 to move towards the magnetic powder core on the support frame, the push plate 2018 provides thrust for the magnetic powder core, so that the magnetic powder core is separated from the support frame, the magnetic powder core is prevented from being adhered to the support frame, and the magnetic powder core is convenient to take down.

In order to further describe the technical means and effects adopted by the present invention for achieving the intended purpose, the following detailed description will refer to the specific implementation, structure, characteristics and effects according to the present invention with reference to the accompanying drawings and preferred embodiments.

The present invention is not limited to the above embodiments, but is capable of modification and variation in detail, and other modifications and variations can be made by those skilled in the art without departing from the scope of the present invention.

Claims

1. An anti-adhesion magnetic powder core sintering device comprises a sintering furnace (7), and is characterized in that: a supporting plate (5) is arranged on one side of the sintering furnace (7), a limit groove (4) is formed in the top surface of the supporting plate (5), a sliding seat (3) is slidably arranged in the limit groove (4), and a taking mechanism (2) for taking out a supporting frame filled with a magnetic powder core is arranged at the top of the sliding seat (3);

the taking mechanism (2) comprises a first rotating rod (206) and a second rotating rod (204) which are hinged to the sliding seat (3), one ends of the first rotating rod (206) and the second rotating rod (204) are jointly hinged to a taking rod (203), a spring lock catch (202) is fixedly arranged at one end, close to the sintering furnace (7), of the taking rod (203), a hydraulic cylinder (205) for driving the second rotating rod (204) is further rotatably arranged on the sliding seat (3), and a transmission mechanism (201) is arranged at one end, close to the sintering furnace (7), of the sliding seat (3);

the anti-adhesion device comprises a transmission mechanism (201), and is characterized in that the transmission mechanism (201) comprises a fixing frame (2012) fixedly connected with a sliding seat (3), two guide rails (2013) are fixedly arranged at the bottom of the fixing frame (2012), anti-adhesion units for pushing magnetic powder cores are slidably arranged between the two guide rails (2013), a rotating plate (2014) is rotatably arranged on the sliding seat (3), second sliding grooves are formed in two sides of the rotating plate (2014), a transmission rod (2016) is hinged to the middle of a first rotating rod (206), one end of the transmission rod (2016) is fixedly connected with a second deflector rod, the second deflector rod is movably connected with one second sliding groove, each anti-adhesion unit comprises a moving plate (2011) slidably arranged between the two guide rails (2013), a pushing plate (2018) is fixedly arranged at the bottom of each moving plate (2011), one end of each moving plate (2011) far away from the pushing plate (2018) is fixedly provided with a rotating seat (2017), a first deflector rod is fixedly connected with the bottom of each rotating seat (2017), and the second deflector rod is fixedly connected with two sliding blocks (2019) through the corresponding sliding blocks (2019).

2. An anti-adhesion magnetic powder core sintering device according to claim 1, characterized in that the inlet of the sintering furnace (7) is hinged with a sealing door (1).

3. An anti-adhesion magnetic powder core sintering device according to claim 1, characterized in that the bottom of the sintering furnace (7) is fixedly provided with two bases (6).