CN113278787A - Metal material surface heat treatment system - Google Patents

Abstract

The invention relates to the technical field of metal heat treatment, in particular to a metal material surface heat treatment system, which comprises a machine base, an alternating current heating inductor, a power supply device and a cooling box, wherein the alternating current heating inductor, the power supply device and the cooling box are all arranged on the machine base, the power supply device is electrically connected with the alternating current heating inductor, and the metal material surface heat treatment system also comprises: the mounting assembly is movably arranged on the base and used for fixing materials to be processed; the driving assembly is connected with the mounting assembly, is arranged on the base and is used for adjusting the position of the mounting assembly; the mounting assembly at least comprises a monitoring unit for monitoring the distance between the material to be processed and the alternating current heating inductor; the phenomenon that the rotation time of the material is advanced or delayed due to manual control of workers is avoided, electric energy is saved, and the heat treatment effect is guaranteed.

Description

Metal material surface heat treatment system

Technical Field

The invention relates to the technical field of metal heat treatment, in particular to a metal material surface heat treatment system.

Background

The metal heat treatment is a process of heating a metal or alloy workpiece in a certain medium to a proper temperature, keeping the temperature for a certain time, cooling the workpiece in different media at different speeds, and controlling the performance of the workpiece by changing the microstructure of the surface or the interior of a metal material.

Among them, circular ring-shaped metal materials are very common in the mechanical field, for example, gears, the surfaces of which need to be heat-treated when the gears are used, so as to prolong the service life of the gears or other circular ring-shaped metal materials, and the existing heat treatment systems mostly adopt an induction heating surface quenching mode.

Current induction heating surface hardening heat treatment device needs staff manual control material through heating the inductor and need control the material when passing through the inductor and rotate, makes it be heated evenly, but, staff if misoperation, lead to rotating in advance, can consume the electric energy, rotate the opportunity and postpone, can lead to thermal treatment effect not good.

Disclosure of Invention

The present invention is directed to a system for heat treatment of a surface of a metal material, so as to solve the above problems.

In order to achieve the purpose, the invention provides the following technical scheme:

the utility model provides a metal material surface heat treatment system, includes frame, alternating current heating inductor, power supply ware and cooler bin are all installed on the frame, the power supply ware with alternating current heating inductor electric connection still includes:

the mounting assembly is movably arranged on the base and used for fixing materials to be processed; and

the driving assembly is connected with the mounting assembly, is arranged on the base and is used for adjusting the position of the mounting assembly;

the mounting assembly at least comprises a monitoring unit for monitoring the distance between the material to be processed and the alternating current heating inductor;

the drive assembly at least comprises a power output source and a drive source, the power output source is connected with the drive source, the drive source comprises a linear motion module and a circumferential motion module, and the circumferential motion module is electrically connected with the monitoring unit.

The application further adopts the technical scheme that: the mounting assembly further comprises:

the mounting seat is connected with the driving assembly;

the supporting mechanism is arranged on the mounting seat and used for supporting the material to be processed;

the positioning mechanism is arranged on the mounting seat and used for fixing the position of the material to be processed; and

the trigger module is arranged between the supporting mechanism and the mounting seat;

the trigger module detects the contact state between the material to be processed and the supporting mechanism and controls the positioning mechanism and the power output source to work.

The application further adopts the technical scheme that: the number of the supporting mechanisms is at least one group, and the supporting mechanisms at least comprise adjusting seats and processing platforms;

the adjusting seat is movably arranged on the mounting seat, the processing platform is movably arranged on the adjusting seat, and the processing platform and the mounting seat are both elastically connected with the adjusting seat.

The application further adopts the technical scheme that: the positioning mechanism includes:

the positioning seat is arranged on the mounting seat;

the positioning rods are movably arranged on the positioning seat and are elastically connected with each other; and

the second power source is arranged between the positioning rod and the positioning seat and used for adjusting the position of the positioning rod on the positioning seat;

the second power source is electrically connected with the trigger module.

This application still further technical scheme: the monitoring unit at least comprises a sliding part, a thermal change part and a conductive part;

the sliding piece is movably arranged in a cavity formed in the mounting seat, and the sliding piece is elastically connected with the inner wall of the cavity;

the thermal change piece is arranged between the sliding piece and the inner wall of the cavity, and the position of the sliding piece is adjusted when the thermal change piece receives heat;

the number of the conductive pieces is at least one group, and each group of the conductive pieces is arranged between the sliding piece and the mounting seat.

This application still further technical scheme: the linear motion module is connected with the power output source and comprises a driving sleeve and an output rod;

the driving sleeve is arranged on the base and provided with a hole groove for the output rod to slide;

the power output source and the mounting assembly are connected with the output rod, and the circumferential motion module is arranged between the output rod and the driving sleeve.

This application still further technical scheme: an input hole is formed in the driving sleeve, the input hole is communicated with the power output source, and the power output source can inject transmission media into the driving sleeve;

the output rod is in sealing fit with the inner wall of the driving sleeve.

The application adopts a further technical scheme that: the circumferential motion module includes:

the spiral groove is formed on the inner wall of the driving sleeve;

the sliding seats are movably arranged on the output rod, the number of the sliding seats is at least one, and the sliding seats are elastically connected with the output rod;

balls slidably fitted on the sliding seats, the number of the balls being the same as that of the sliding seats, an

The first power source is arranged between the sliding seat and the output rod and used for adjusting the position of the sliding seat.

Compared with the prior art, the technical scheme provided by the embodiment of the invention has the following beneficial effects:

according to the embodiment of the invention, the driving source with linear and circumferential motion modes is controlled by arranging the power output source, so that under the condition of ensuring that the materials are conveyed and heated uniformly during heat treatment, the whole process adopts mechanical automatic control, the materials automatically rotate when approaching the alternating current heating inductor, the phenomenon that the rotation time of the materials is advanced or delayed due to manual control of workers is further avoided, the electric energy is saved, and the heat treatment effect is ensured.

Drawings

FIG. 1 is a schematic structural diagram of a system for heat treatment of a surface of a metal material according to an embodiment of the present invention;

FIG. 2 is an enlarged schematic structural view of a portion A of the system for heat treatment of a surface of a metal material according to an embodiment of the present invention;

FIG. 3 is a schematic structural view of a driving source in the heat treatment system for a surface of a metallic material according to an embodiment of the present invention;

FIG. 4 is an enlarged schematic view of a portion B of a heat treatment system for a surface of a metallic material according to an embodiment of the present invention;

FIG. 5 is a schematic structural diagram of a processing platform and a skidproof bump in the heat treatment system for the surface of a metal material in the embodiment of the invention.

The reference numerals in the schematic drawings illustrate:

1-machine base, 2-power supply, 3-alternating current heating inductor, 4-cooling box, 5-fan, 6-driving source, 61-driving sleeve, 62-input hole, 63-output rod, 64-spiral groove, 65-sliding seat, 66-ball, 67-first electromagnet, 7-mounting seat, 8-material guide rod, 9-processing platform, 10-anti-skid projection, 11-adjusting seat, 12-contact, 13-positioning seat, 14-positioning rod, 15-second electromagnet, 16-heat insulation layer, 17-air bag, 18-piston and 19-electrode plate.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be obtained by a person skilled in the art without making any creative effort based on the embodiments of the present invention, belong to the protection scope of the present invention, and the present invention is further described with reference to the embodiments below.

Referring to fig. 1-5, in an embodiment of the present application, a system for heat-treating a surface of a metal material includes a base 1, an ac heating inductor 3, a power supply 2, and a cooling box 4, wherein the ac heating inductor 3, the power supply 2, and the cooling box 4 are all mounted on the base 1, the power supply 2 is electrically connected to the ac heating inductor 3, and the system further includes:

the mounting assembly is movably arranged on the machine base 1 and used for fixing materials to be processed; and

the driving assembly is connected with the mounting assembly, is arranged on the machine base 1 and is used for adjusting the position of the mounting assembly;

the mounting assembly at least comprises a monitoring unit for monitoring the distance between the material to be processed and the alternating current heating inductor 3;

the drive assembly at least comprises a power output source and a drive source 6, the power output source is connected with the drive source 6, the drive source 6 comprises a linear motion module and a circumferential motion module, and the circumferential motion module is electrically connected with the monitoring unit.

It should be noted that, as shown in fig. 1, the ac heating inductor 3 is located right above the cooling box 4, so that the heat-treated metal material can be directly cooled along the moving path, and the whole processing flow is smoother.

In addition, the power supply component may adopt an energy storage battery pack or directly adopt a mode that a plug is connected with a power supply circuit, as long as power supply to the alternating current heating inductor 3 can be realized, and is not specifically limited herein.

In practical application, materials to be processed (to be explained, the present application mainly aims at ring-shaped or middle hollow materials, such as gears and the like) are fixed on the mounting assembly, when the fixing work of the materials to be processed is completed, the power output source works to drive the linear motion module to work to drive the materials to be processed to move downwards in the direction shown in fig. 1 until the materials to be processed approach the alternating current heating inductor 3, at this time, part of the mounting assembly passes through the alternating current heating inductor 3, the surface of the mounting assembly is heated through the cutting magnetic induction line work of the alternating current heating inductor 3, at this time, the circumferential motion module is triggered by the monitoring unit to work, the materials to be processed rotate while moving downwards through the synchronous motion of the circumferential motion module and the linear motion module, so that the surface of the whole processed materials is uniformly heated, and the heat treatment effect is better, and whole flow automation degree is high, when avoiding staff manual control, appears in advance or postpone above the time and leads to the electric energy loss or the phenomenon that treatment effect is not good to cool off through cooler bin 4 finally.

Referring to fig. 1, 2 and 5, as a preferred embodiment of the present application, the mounting assembly further includes:

the mounting seat 7 is connected with the driving assembly;

the supporting mechanism is arranged on the mounting seat 7 and used for supporting the material to be processed;

the positioning mechanism is arranged on the mounting seat 7 and used for fixing the position of the material to be processed; and

the trigger module is arranged between the supporting mechanism and the mounting seat 7;

the trigger module detects the contact state between the material to be processed and the supporting mechanism and controls the positioning mechanism and the power output source to work.

In a specific case of this embodiment, the number of the supporting mechanisms is at least one group, and the supporting mechanisms at least include the adjusting seat 11 and the processing platform 9;

adjust the seat 11 activity setting and be in on the mount pad 7, machining platform 9 movable mounting be in adjust on the seat 11, machining platform 9 with mount pad 7 all with adjust 11 elastic connection of seat.

It should be noted that, as shown in fig. 2, the processing platform 9 is hinged to one end of the mounting base 7 through a material guiding rod 8, so as to facilitate the installation of the material to be processed.

In addition, as shown in fig. 5, a plurality of anti-skid protrusions 10 are arranged on the processing platform 9 to improve the frictional resistance between the material to be processed and the processing platform 9, and it should be noted that, as shown in fig. 2, when the adjusting seat 11 is still, a space exists between the lower side of the adjusting seat 11 and the mounting seat 7.

When in actual application, with the annular pending material by the lower extreme rebound as mount pad 7 shown in fig. 2, because the internal diameter of annular material is different, make the material at the in-process that shifts up, guide rod 8 takes place the displacement, make processing platform 9 follow it and take place the displacement, avoid causing the blockking to the removal of material, and when the material was put on processing platform 9, trigger positioning mechanism work through trigger module, fix the position of material, trigger power take off source work simultaneously, the control material is towards the direction motion of alternating current heating inductor 3.

Referring to fig. 2, as another preferred embodiment of the present application, the positioning mechanism includes:

a positioning seat 13 disposed on the mounting seat 7;

the number of the positioning rods 14 is at least two, and the positioning rods 14 are movably arranged on the positioning seat 13 and are elastically connected with each other; and

the second power source is arranged between the positioning rod 14 and the positioning seat 13 and is used for adjusting the position of the positioning rod 14 on the positioning seat 13;

the second power source is electrically connected with the trigger module.

In particular, in order to improve the positioning effect on the annular material, as shown in fig. 2, the positioning rods 14 are symmetrically arranged on the positioning seat 13.

The second power source is preferably a set of second electromagnets 15, and a set of second electromagnets 15 is disposed between the positioning seat 13 and the positioning rod 14, however, the second power source is not limited to a mechanical structure or element with electromagnets, and may also be driven by an electric telescopic rod or a linear motor.

In this embodiment, the triggering module includes a set of contacts 12, and the set of contacts 12 is disposed between the processing platform 9 and the mounting base 7, but the triggering module is not limited to the above-mentioned mechanical conduction manner, and may also adopt a plug and socket mating manner or a conductive block, and the like, and is not limited herein.

When the material to be processed is placed on processing platform 9, under the action of gravity of material, drive and adjust seat 11 and move down, contact between contact 12, trigger the circular telegram between second electro-magnet 15 and repel each other for locating lever 14 contradicts the inner wall of cyclic annular material, realizes the location work to the material, and triggers power take off source work simultaneously, adjusts the position of material.

Referring to fig. 2, as another preferred embodiment of the present application, the monitoring unit at least includes a sliding component, a thermal component and a conductive component;

the sliding piece is movably arranged in a cavity formed in the mounting seat 7, and the sliding piece is elastically connected with the inner wall of the cavity;

the thermal change piece is arranged between the sliding piece and the inner wall of the cavity, and the position of the sliding piece is adjusted when the thermal change piece receives heat;

the number of the conductive pieces is at least one group, and each group of the conductive pieces is arranged between the sliding piece and the mounting seat 7.

It should be noted that the sliding member is preferably a piston 18, and the piston 18 is slidably mounted in the cavity, but the sliding member is not limited to a replacement of the piston 18, and may also be a metal block or a module, and is not limited herein.

In addition, a heat insulation layer 16 is attached to the inner wall of the cavity and used for blocking heat of the alternating current heating inductor 3 acting on the surface of the mounting seat 7.

Without limitation, the thermal change element is preferably a balloon 17 in the present application, and the balloon 17 is disposed between the thermal insulation layer 16 and the piston 18, but the thermal change element may also be a balloon or a temperature sensor cooperating with a linear motor, and is not limited thereto.

In this embodiment, the conductive piece is preferably an electrode pad 19, but the electrode pad 19 is not the only replacement of the conductive piece, and a plug and socket mating manner, a conductive block, or the like may also be adopted, and is not limited herein.

When the material to be processed approaches the alternating current heating inductor 3 along with the installation assembly, as shown in fig. 2, the lower end part region of the installation seat 7 causes cutting magnetic induction line work to the alternating current heating inductor 3, so that the lower end surface of the installation seat 7 is heated, and under the action of thermal expansion and cold contraction, the air bag 17 is expanded, at the moment, through the collision effect between the air bag 17 and the piston 18, the piston 18 moves upwards and makes contact between the electrode plates 19, and the circumferential movement module is triggered to be electrified to work.

Referring to fig. 3 and 4, as another preferred embodiment of the present application, the linear motion module is connected to the power output source, and includes a driving sleeve 61 and an output rod 63;

the driving sleeve 61 is installed on the base 1, and a hole groove for the output rod 63 to slide is formed in the driving sleeve 61;

the power output source and the mounting assembly are connected with the output rod 63, and the circumferential motion module is arranged between the output rod 63 and the driving sleeve 61.

In the embodiment, for example, an input hole 62 is formed on the driving sleeve 61, the input hole 62 communicates with the power output source, and the power output source can inject a transmission medium into the driving sleeve 61;

the output rod 63 is in sealing fit with the inner wall of the driving sleeve 61.

It should be specifically noted that the transmission medium may be liquid or gas, in this embodiment, the transmission medium is preferably gas, and of course, the power output source is preferably a fan 5, and of course, a manner of matching an air pump or an air cylinder with a linear motor may also be adopted, and if the transmission medium is liquid, the power output source may be driven by a water pump, which is not limited herein.

When the contacts 12 are contacted, the fan 5 is powered on to work, air flow is injected into the driving sleeve 61, and under the interference effect between the air flow and the output rod 63, the output rod 63 is driven to extend out of the driving sleeve 61, so that the material to be processed is driven to move towards the direction of the alternating current heating inductor 3.

Referring to fig. 3 and 4, as another preferred embodiment of the present application, the circumferential motion module includes:

a spiral groove 64 formed on an inner wall of the driving sleeve 61;

the sliding seats 65 are movably mounted on the output rod 63, the number of the sliding seats 65 is at least one, and the sliding seats 65 are elastically connected with the output rod 63;

balls 66 slidably fitted on the sliding seats 65, the number of the balls 66 being the same as that of the sliding seats 65, an

And the first power source is arranged between the sliding seat 65 and the output rod 63 as well as between the sliding seat 65 and the output rod 63 and is used for adjusting the position of the sliding seat 65.

Without limitation, the first power source is preferably a set of first electromagnets 67, and a set of first electromagnets 67 is disposed between the positioning seat 13 and the positioning rod 14, however, the first power source is not limited to a mechanical structure or element with electromagnets, and may also be driven by an electric telescopic rod or a linear motor.

In addition, as shown in fig. 3, the overall length of the spiral groove 64 only occupies a section of the length of the driving sleeve 61, that is, the initial section of the spiral groove 64 is just the position for triggering the first power source to work, so as to avoid the linear motion work caused by the influence of the spiral groove 64.

When the electrode plates 19 are contacted, the first electromagnets 67 are triggered to be electrified and repelled, so that the sliding seat 65 and the balls 66 extend out of the output rod 63, the balls 66 and the spiral grooves 64 are matched, the output rod 63 moves downwards and rotates under the action of air flow, materials are rotated when heated, and the surfaces of the materials are uniformly heated.

It should be noted that, the elastic connection in the above embodiments may be implemented by a spring, an elastic steel plate, an elastic sheet, or an elastic rubber structure, and the like, which are not specifically limited herein, and in addition, all the circuits related to the electrical connection in the above embodiments have the power supply 2 to supply power uniformly, which is not specifically described herein.

The working principle of the application is as follows: the circular material to be processed is moved upwards from the lower end of the mounting base 7 shown in fig. 2, because the inner diameter of the circular material is different, the material guide rod 8 is displaced in the process of moving upwards, the processing platform 9 is displaced along with the material guide rod to avoid blocking the movement of the material, when the material is placed on the processing platform 9, the trigger module triggers the positioning mechanism to work, the position of the material is fixed, when the contacts 12 are contacted, the fan 5 is electrified to work, air flow is injected into the driving sleeve 61, under the interference effect between the air flow and the output rod 63, the output rod 63 is driven to extend out of the driving sleeve 61, the material to be processed is driven to move towards the alternating current heating inductor 3, the material to be processed is driven to move downwards as shown in fig. 1, until the material to be processed is close to the alternating current heating inductor 3, part installation component passes alternating current heating inductor 3, through the work of cutting magnetic induction line to alternating current heating inductor 3, make the installation component surface heat up, contact between the electrode piece 19 this moment, it repulses to trigger circular telegram between the first electro-magnet 67, and then make sliding seat 65 and ball 66 stretch out from output rod 63, cooperate between ball 66 and the helicla flute 64 this moment, and under the effect of air current, output rod 63 takes place to rotate when moving down this moment, and then make the material rotate when being heated, make each face of material be heated evenly, the thermal treatment effect is better, and whole flow automation degree is high, when avoiding staff's manual control, appear in advance or postpone above the time and lead to the electric energy loss or the not good phenomenon of treatment effect.

The present invention and its embodiments have been described above schematically, without limitation, and what is shown in the drawings is only one of the embodiments of the present invention, and the actual structure is not limited thereto. Therefore, if the person skilled in the art receives the teaching, without departing from the spirit of the invention, the person skilled in the art shall not inventively design the similar structural modes and embodiments to the technical solution, but shall fall within the scope of the invention.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (8)

1. The utility model provides a metal material surface heat treatment system, includes frame, alternating current heating inductor, power supply ware and cooler bin are all installed on the frame, the power supply ware with alternating current heating inductor electric connection, its characterized in that still includes:

the mounting assembly is movably arranged on the base and used for fixing materials to be processed; and

the driving assembly is connected with the mounting assembly, is arranged on the base and is used for adjusting the position of the mounting assembly;

the mounting assembly at least comprises a monitoring unit for monitoring the distance between the material to be processed and the alternating current heating inductor;

the drive assembly at least comprises a power output source and a drive source, the power output source is connected with the drive source, the drive source comprises a linear motion module and a circumferential motion module, and the circumferential motion module is electrically connected with the monitoring unit.

2. A metallic material surface heat treatment system as set forth in claim 1 wherein the mounting assembly further comprises:

the mounting seat is connected with the driving assembly;

the supporting mechanism is arranged on the mounting seat and used for supporting the material to be processed;

the positioning mechanism is arranged on the mounting seat and used for fixing the position of the material to be processed; and

the trigger module is arranged between the supporting mechanism and the mounting seat;

the trigger module detects the contact state between the material to be processed and the supporting mechanism and controls the positioning mechanism and the power output source to work.

3. The metal material surface heat treatment system according to claim 2, wherein the number of the supporting mechanisms is at least one group, and the supporting mechanisms at least comprise adjusting seats and processing platforms;

the adjusting seat is movably arranged on the mounting seat, the processing platform is movably arranged on the adjusting seat, and the processing platform and the mounting seat are both elastically connected with the adjusting seat.

4. The system for surface heat treatment of metallic material according to claim 2 or 3, wherein the positioning mechanism comprises:

the positioning seat is arranged on the mounting seat;

the positioning rods are movably arranged on the positioning seat and are elastically connected with each other; and

the second power source is arranged between the positioning rod and the positioning seat and used for adjusting the position of the positioning rod on the positioning seat;

the second power source is electrically connected with the trigger module.

5. A surface heat treatment system for metallic material according to claim 1, wherein said monitoring unit comprises at least a sliding member, a thermal changing member, and a conductive member;

the sliding piece is movably arranged in a cavity formed in the mounting seat, and the sliding piece is elastically connected with the inner wall of the cavity;

the thermal change piece is arranged between the sliding piece and the inner wall of the cavity, and the position of the sliding piece is adjusted when the thermal change piece receives heat;

the number of the conductive pieces is at least one group, and each group of the conductive pieces is arranged between the sliding piece and the mounting seat.

6. A metal material surface heat treatment system as recited in claim 1 wherein said linear motion module is connected to said power take off source, said linear motion module including a drive sleeve and an output rod;

the driving sleeve is arranged on the base and provided with a hole groove for the output rod to slide;

the power output source and the mounting assembly are connected with the output rod, and the circumferential motion module is arranged between the output rod and the driving sleeve.

7. The metal material surface heat treatment system according to claim 6, wherein an input hole is formed on the driving sleeve, the input hole is communicated with the power output source, and the power output source can inject a transmission medium into the driving sleeve;

the output rod is in sealing fit with the inner wall of the driving sleeve.

8. A metal material surface heat treatment system as set forth in claim 6, wherein said circumferential motion module comprises:

the spiral groove is formed on the inner wall of the driving sleeve;

the sliding seats are movably arranged on the output rod, the number of the sliding seats is at least one, and the sliding seats are elastically connected with the output rod;

balls slidably fitted on the sliding seats, the number of the balls being the same as that of the sliding seats, an

The first power source is arranged between the sliding seat and the output rod and used for adjusting the position of the sliding seat.

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