CN213856887U - Automatic heating furnace - Google Patents

Abstract

The utility model discloses an automatic heating furnace, which comprises a heating furnace body, wherein a first conveying belt is arranged at the front end of a furnace inlet of the heating furnace body; the tail end of first conveyer belt is provided with first rotary disk, and it has the first holding tank that a plurality of can accept the material on the first conveyer belt to distribute on the first rotary disk. The lower part of first rotary disk is equipped with the receiving piece, and is provided with the punishment in advance passageway that runs through the upper and lower both ends face of receiving piece on the receiving piece, and when the first holding tank that holds the material rotated to punishment in advance passageway top, the material fell into the punishment in advance passageway. The second rotating disc is located below the receiving piece, a plurality of second containing grooves are formed in the disc wall of the second rotating disc along the circumferential direction, and when the second containing grooves rotate to the discharge port of the material passing channel, the second containing grooves receive materials in the material passing channel. The second conveying belt is positioned below the second rotating disc and used for receiving materials in the second accommodating groove; the pushing assembly pushes the materials on the second conveying belt to enter the heating furnace body. The materials enter the furnace one by one to be heated, and the heating is sufficient.

Description

Automatic heating furnace

Technical Field

The utility model relates to a heat stove equipment technical field, more specifically the theory says, relates to an automatic heat stove.

Background

Forging is a common process in machining processes, and to achieve certain properties, materials need to be forged to achieve that property. The high temperature heating of the material is necessary before forging, for example, the heating of iron material is usually above 1000 ℃, even up to 1300 ℃. The heating furnace is indispensable processing equipment in the forging processing, adopts coal burning, electric power generation or gas combustion heating, and the material gets into furnace from furnace body one end, falls out from the discharge gate of the furnace body other end after heating structure heating in the furnace, puts into the in-process of material heating, pushes the material removal of leading income through the material of putting into behind, or carries the material through the chain. However, in the moving heating process, the heating temperature of the material needs to be accurately detected to judge whether the required heating requirement is met. The 'push steel type natural gas forging heating furnace' with the application number of '201310570040.5' provides a heating furnace which is provided with a temperature measuring device and can measure the instant temperature of a heated material. However, the above-mentioned heating furnace still has the following problems:

1. the automatic feeding cannot be realized, manual filling is needed, and the working efficiency is relatively low.

2. When the material is filled, the distribution is not uniform, the heating is insufficient in places with more materials, and the heating temperature is too high in places with less materials, so that the characteristics of the materials are influenced.

Disclosure of Invention

In order to solve the technical problem, the utility model aims at providing a get into the stove of heating that heats body realization automatic feeding through horizontal transport mechanism autoloading material, and separate between material and the material through two rolling discs at the material loading in-process, guarantee that the material gets into the stove body of heating one by one and heats in order to realize that the material heating is abundant even.

Solve the technical problem, the utility model discloses take following technical scheme:

an automatic heating furnace comprises a heating furnace body, wherein a feeding device is arranged at the front end of a furnace inlet of the heating furnace body; the loading attachment includes horizontal conveying mechanism, horizontal conveying mechanism includes:

the supporting seat is provided with a supporting plate and a first conveying belt for receiving materials and conveying the materials;

the first rotating disc is positioned at the tail end of the first conveying belt, is coaxially connected with a first driving motor and rotates around the center of a circle of the first driving motor;

the first containing grooves are uniformly distributed on the first rotating disc along the circumferential direction, and when the first containing grooves rotate to the first conveying belt along with the first rotating disc, the first containing grooves can contain materials on the first conveying belt and rotate continuously;

the bearing piece is positioned below the first rotating disc and fixedly connected with the supporting plate, and provides bottom support for the first rotating disc and materials in the first accommodating groove; the bearing piece is provided with a material passing channel penetrating through the upper end surface and the lower end surface of the bearing piece, and when the first accommodating tank accommodating materials rotates to the position above the material passing channel, the materials fall into the material passing channel;

the second rotating disc is positioned below the bearing piece, and a second driving motor connected with the supporting plate is coaxially connected to the second rotating disc and rotates around the circle center of the second rotating disc under the action of the second driving motor; the axial direction of the second rotating disc is perpendicular to the axial direction of the first rotating disc, a plurality of second accommodating grooves capable of accommodating single materials are formed in the disc wall of the second rotating disc along the circumferential direction, the disc wall of the second rotating disc abuts against a discharge port of the material passing channel, and when the second accommodating grooves rotate to the discharge port of the material passing channel, the second accommodating grooves accommodate the materials in the material passing channel and rotate continuously;

the second conveying belt is positioned below the second rotating disc and used for receiving materials in the second accommodating groove and conveying the materials;

the pushing assembly is arranged at the tail end of the second conveying belt and used for pushing the materials on the second conveying belt to enter the heating furnace body; the chain that is used for carrying the material is arranged in the heating furnace body, and the material that is pushed into the heating furnace body by the pushing assembly is accepted and carried by the chain.

In a further scheme, the discharge port of the material passing channel is an arc-shaped opening which can be attached to the disc wall of the second rotating disc, a through groove is formed in the side wall, located in the feeding direction of the second rotating disc, of the receiving piece, the through groove is communicated with the material passing channel, the depth of the second accommodating groove is smaller than the height of the material, the length of the through groove is smaller than the height of the material, and the length of the through groove and the depth of the second accommodating groove are larger than the height of the material. And the subsequent material is prevented from overflowing from the gap between the material passing channel and the second rotating disc. And the depth of the second accommodating groove is smaller than the height of the material, the length of the through groove and the depth of the second accommodating groove are larger than the height of the material, and the second rotating disc is prevented from interfering with subsequent materials to influence rotation in the rotating process.

In a further scheme, a baffle plate used for limiting the material in the material passing channel is arranged on the side wall of the bearing piece at the material passing channel. Preventing the leakage of the materials.

In a further scheme, the material passing channel is sequentially divided into a diameter reduction section, a straight line section and a buffer section from top to bottom, the inner diameter of the material passing channel at the upper end of the diameter reduction section is larger than the inner diameter of the material passing channel at the lower end of the diameter reduction section, and the inner diameter of the material passing channel at the straight line section is the same as the inner diameter of the lower end of the diameter reduction section and can only contain one material; the material passing channel extends downwards in the buffer section in an inclined mode, and an included angle is formed between the buffer section and the straight line section. Prevent through the reduction of diameter section that the material whereabouts process from taking place to interfere with first rotary disk, and the internal diameter through the straightway only can hold a material for the material is arranged neatly one by one along vertical direction. Simultaneously, the buffering section is inclined and extends downwards to buffer the materials, so that the materials are prevented from directly impacting the second rotating disc, and the service life of the second rotating disc is prolonged.

In a further scheme, the pushing assembly comprises a pushing cylinder and a pushing plate, and the pushing plate is connected with the pushing cylinder and pushes the material on the second conveying belt to enter the heating furnace body under the action of the pushing cylinder; the pushing cylinder drives the pushing plate to push the materials on the second conveying belt, and the arc plate moves to one side of the second rotating disc to limit the materials in the second rotating disc; when the pushing cylinder drives the push plate to reset, the arc-shaped plate is far away from the second rotating disc.

In a further scheme, limiting plates are arranged on two sides of the first conveying belt, and the limiting plates located on two sides of the first conveying belt are tangent to the first rotating disc.

In a further aspect, an opening is provided on an upper end surface of the receiving member, and the first driving motor is disposed in the opening. The floor area of the equipment is reduced, and the utilization rate of the air is improved.

In a further scheme, loading attachment still includes vertical conveying mechanism, vertical conveying mechanism includes the feeding case, be provided with lifting unit in the feeding case, lifting unit includes the polylith fly leaf, the polylith fly leaf is the echelonment by low to high in vertical direction and arranges, and the difference in height between per two adjacent fly leaves is greater than the height of material, the bottom of polylith fly leaf is through a connecting plate fixed connection, the bottom of connecting plate is connected with the lift cylinder, is equipped with the fixed plate between per two adjacent fly leaves, the both sides of fixed plate and the both sides inner wall fixed connection of feeding case, the last face of fly leaf and the last face of fixed plate are the inclined plane that extends and slope and set up downwards to the direction of highest fly leaf.

In a further scheme, the feeding device further comprises a material lifting mechanism, the material lifting mechanism comprises a fixed frame and a material carrying vehicle for carrying materials, a guide rail is arranged on the fixed frame along the height direction of the fixed frame, a pulley is slidably arranged on the guide rail, and the pulley is connected with the material carrying vehicle; the upper end of the fixed frame is provided with an electric hoist, and the electric hoist is connected with the material carrying vehicle through a connecting rod so as to drive the material carrying vehicle to do lifting action along a guide rail; and the guide rail is divided into a linear guide rail and a bent guide rail from bottom to top, and after the material carrying vehicle enters the bent guide rail, the material carrying vehicle dumps towards the feed inlet of the feed box.

In a further scheme, the chain-type heating furnace further comprises a controller, a third driving motor and a temperature sensor, wherein the temperature sensor is arranged on the heating furnace body, the third driving motor is connected with the chain to drive the chain to operate, the third driving motor and the temperature sensor are respectively connected with the controller, and after the temperature sensor detects that the temperature of materials in the heating furnace body on the chain is smaller than a preset value, the third driving motor is controlled by the controller to drive the chain to operate in a speed reduction mode.

Advantageous effects

1. The first conveying belt is used for receiving materials and conveying the materials, and the materials are divided into a plurality of rows and then are conveyed at intervals one by one through the first rotating disc. Dividing the materials into a plurality of rows on a first rotating disc, and conveying the materials row by row at intervals; carry the line by line interval formula with the material through the second rolling disc, because first rolling disc has divided into the material into the multiseriate back row by row interval formula and carries, the material after the split of second rolling disc is single material promptly, gets into and heats more abundant also more even behind the stove that heats.

2. Promote through promoting the subassembly material on the second conveyer belt gets into the stove body of heating need not artifical filler, convenient and fast more, and work efficiency is higher, also avoids appearing the incident.

Drawings

FIG. 1 is a schematic structural view of an automatic heating furnace without a material lifting mechanism;

FIG. 2 is an enlarged view of portion A of FIG. 1;

FIG. 3 is a schematic structural view of the first rotary disk, the receiving member and the second rotary disk;

FIG. 4 is a schematic view of the receiving member of FIG. 3 without the stop plate;

FIG. 5 is an enlarged view of portion B of FIG. 4;

FIG. 6 is a schematic view of the receiving member;

FIG. 7 is a schematic view of the receiving member with the first driving motor mounted thereon;

FIG. 8 is a partial side view of the lateral transport mechanism;

FIG. 9 is an enlarged view of portion C of FIG. 8;

FIG. 10 is a schematic view of the lifting assembly;

FIG. 11 is a side view of the lifting mechanism in a material dumping condition;

fig. 12 is a front view of the lifting mechanism in an idle state.

The reference numerals in the schematic drawings illustrate:

1-a heating furnace body, 2-a material lifting mechanism, 21-a fixed frame, 22-a material carrying vehicle, 23-a guide rail, 231-a linear guide rail, 232-a curved guide rail, 24-an electric hoist, 25-a connecting rod, 3-a longitudinal conveying mechanism, 31-a feeding box, 32-a lifting component, 321-a movable plate, 322-a connecting plate, 323-a lifting cylinder, 324-a guide column, 325-a fixed plate, 326-a guide plate, 4-a transverse conveying mechanism, 41-a supporting seat, 42-a first conveying belt, 43-a first rotating disc, 431-a first accommodating groove, 44-a first driving motor, 45-a limiting plate, 46-a supporting plate, 47-a bearing part, 471-an opening, 472-a through groove and 473-a baffle, 48-material passing channel, 481-diameter reduction section, 482-straight section, 483-buffer section, 49-second rotating disc, 491-second accommodating groove, 410-second driving motor, 411-second conveying belt, 412-push plate, 413-arc plate and 5-material.

Detailed Description

For a further understanding of the present invention, reference will now be made in detail to the present invention, examples of which are illustrated in the accompanying drawings.

In the description of the present invention, it is to be understood that the terms "center", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

Referring to fig. 1-12, the present embodiment provides an automatic heating furnace, which includes a heating furnace body 1, and a feeding device is disposed at a front end of a furnace inlet of the heating furnace body 1. The feeding device comprises a lifting mechanism 2, a longitudinal conveying mechanism 3 and a transverse conveying mechanism 4. And the material lifting mechanism 2, the longitudinal conveying mechanism 3 and the transverse conveying mechanism 4 are sequentially arranged along the conveying direction of the material.

In the present scheme, as shown in fig. 11 and 12, the lifting mechanism 2 includes a fixed frame 21 and a material-carrying cart 22 for carrying material. The fixed frame 21 is provided with a guide rail 23 along the height direction thereof, and the guide rail 23 is slidably provided with a pulley which is connected with the material carrying vehicle 22. Meanwhile, the upper end of the fixed frame 21 is provided with an electric hoist 24, the electric hoist 24 is connected with the material carrying vehicle 22 through a connecting rod 25 arc-shaped plate, the upper end of the connecting rod 25 arc-shaped plate is connected with the electric hoist 24, and the lower end of the connecting rod 25 arc-shaped plate is hinged with the bottom end of the material carrying vehicle 22. The material loading trolley 22 is driven by the electric hoist 24 to be matched with the pulley to do lifting motion along the guide rail 23. The guide rail 23 is divided into a linear guide rail 231 and a curved guide rail 232 from bottom to top. After the material loading vehicle 22 enters the curved guide rail 232, the material loading vehicle 22 deflects relative to the center of the curved guide rail 232, so that the material loading vehicle 22 is inclined towards the longitudinal conveying mechanism 3. And the material loading vehicle 22 is lifted by the electric hoist 24, the position of the material loading vehicle 22 in the curved guide rail 232 is different according to the lifting height of the material loading vehicle 22. The position of the carriage 22 in the curved track 232 is different, and the inclination angle of the carriage 22 is different. The greater the angle of inclination of the cart 22, the more material is discharged. The lifting height of the material carrying vehicle 22 is controlled by controlling the electric hoist 24, so that the inclination angle of the material carrying vehicle 22 is controlled, and finally the material discharging quantity and the material discharging speed are controlled.

Referring to fig. 1, 2 and 10, the longitudinal conveying mechanism 3 includes a feeding box 31, and a feeding port of the feeding box 31 is connected to the lifting mechanism 2. The material 5 poured out by the material loading vehicle 22 enters the box from the feeding hole of the feeding box 31. The lifting assembly 32 is arranged in the feeding box 31, specifically, the lifting assembly 32 includes a plurality of movable plates 321, and the plurality of movable plates 321 are arranged in a step shape from low to high in the vertical direction. The height difference between every two adjacent movable plates 321 is greater than the height of the material 5. And the bottoms of the plurality of movable plates 321 are fixedly connected through a connecting plate 322, and the bottom end of the connecting plate 322 is connected with a lifting cylinder 323. The plurality of movable plates 321 are driven by the lifting cylinder 323 to move up and down simultaneously. In the scheme, the two sides of each movable plate 321 are provided with the guide posts 324, and the guide posts 324 are fixedly connected with the inner wall of the feeding box 31. The movable plate 321 is slidably connected to the guide post 324. Meanwhile, a fixed plate 325 arc-shaped plate 413 is arranged between every two adjacent movable plates 321, two sides of the fixed plate 325 arc-shaped plate 413 are fixedly connected with inner walls of two sides of the feeding box 31, and the upper plate surface of the movable plate 321 and the upper plate surface of the fixed plate 325 arc-shaped plate 413 are inclined surfaces which extend towards the direction of the highest movable plate 321 and are obliquely arranged downwards.

A guide plate 326 is provided at the inlet of the inlet box 31, and the material 5 poured out by the material lifting mechanism 2 falls on the guide plate 326 and is guided by the guide plate 326 to fall on the upper end surface of the first movable plate 321 (the movable plate 321 located at the lowest position). Then, the lifting cylinder 323 drives the first movable plate 321 to ascend, and further drives the material 5 to ascend, so that the material 5 slides to the upper end surface of the arc-shaped plate 413 of the next fixed plate 325 and slides downwards along with the upper end surface of the arc-shaped plate 413 of the fixed plate 325 until abutting against the plate surface of the second movable plate 321. Then, the lifting cylinder 323 drives the first movable plate 321 to descend, and the second movable plate 321 descends accordingly, so that the second movable plate 321 is spliced with the arc-shaped plate 413 of the fixed plate 325 to receive the downward-sliding material 5, and the process is sequentially circulated until the last movable plate 321 drives the material 5 to ascend, and the material 5 slides down to the transverse conveying mechanism 4.

It should be noted that, although the number of the movable plates 321 is three in the present embodiment, the number may be four, five, or more than five, and the number of the movable plates 321 is not limited herein.

In this scheme, as shown in fig. 1 and 8, the lateral conveying mechanism 4 includes a supporting seat 41, and a first conveying belt 42 for receiving the material 5 pushed by the movable plate 321 and conveying the material 5 is disposed on the supporting seat 41. When the last moving plate 321 drives the material 5 to rise and the material 5 slides down to the surface of the first conveying belt 42, the first conveying belt 42 drives the material 5 to perform a feeding motion.

The tail end of first conveyer belt 42 is equipped with first rotation dish 43, is connected with first driving motor 44 with the axle center on the first rotation dish 43 and rotates around self centre of a circle under the effect of first driving motor 44. And a plurality of first accommodating grooves 431 capable of accommodating single materials 5 are uniformly distributed on the first rotating disc 43 along the circumferential direction. When the first receiving groove 431 rotates to the end of the first conveying belt 42 along with the rotation of the first rotating disc 43, the first receiving groove 431 receives the material 5 on the first conveying belt 42 and rotates continuously. While during the rotation, the following material 5 is always against the wall of the first rotary disk 43. After the movable plate 321 pushes the material 5 into the first conveying belt 42, the material 5 is stacked on the first conveying belt 42, and each first accommodating groove 431 can receive a single material 5, but it cannot be ensured whether the material 5 is still stacked on the upper end of the material 5, and the material 5 is divided into multiple rows by the first rotating disc 43 and then conveyed in a spaced manner.

And the two sides of the first conveying belt 42 are provided with limiting plates 45 and arc-shaped plates 413, and the limiting plates 45 and arc-shaped plates 413 on the two sides are tangent to the first rotating disc 43. Because the first conveyor belt 42 is continuously operated, the subsequent material 5 moves forward, and the material 5 in front is blocked by the wall of the first rotating disc 43, so that the subsequent material 5 is forced to move towards two sides, and the arc-shaped plate 413 of the limiting plate 45 prevents the material 5 from being separated from the first conveyor belt 42.

The side wall of the supporting seat 41 is further provided with a supporting plate 46, and a bearing piece 47 is fixedly connected to the supporting plate 46. The receiving member 47 is arranged below the first rotating disc 43 to provide a bottom support for the first rotating disc 43 and the material 5 in the first receiving groove 431. The receiving member 47 is provided with a material passing channel 48 penetrating through the upper and lower end surfaces of the receiving member 47. When the first receiving groove 431 containing the material 5 rotates to above the material passing channel 48, the material 5 falls into the material passing channel 48.

As a preferred embodiment, referring to fig. 3-8, the material passing channel 48 is divided into a reduced diameter section 481, a straight section 482 and a buffer section 483 from top to bottom. The inner diameter of the material passing channel 48 at the upper end of the reduced diameter section 481 is larger than the inner diameter of the material passing channel 48 at the lower end of the reduced diameter section 481, and the inner diameter of the material passing channel 48 at the reduced diameter section 481 gradually decreases from the upper end to the lower end. And the inner diameter of the material passing channel 48 in the straight section 482 is the same as that of the lower end of the reduced diameter section 481 and can only receive one material 5. The inner diameter of the material passing channel 48 at the upper end of the reducing section 481 is larger than the inner diameter of the material passing channel 48 at the lower end of the reducing section 481, so that the material 5 is prevented from interfering with the first rotating disc 43 in the process of falling into the material passing channel 48 from the first rotating disc 43 (namely, the upper end of the material 5 is positioned in the first accommodating groove 431 and the lower end of the material 5 is positioned in the material passing channel 48) to influence the rotation of the first rotating disc 43. After entering the reducing section 481, the material 5 slides down along the inner wall of the reducing section 481 and enters the straight section 482. And only one material 5 can be accommodated by the inner diameter of the straight line section 482 so that the materials 5 are aligned one by one in the vertical direction. Meanwhile, the material passing channel 48 extends obliquely downwards from the buffer section 483, and an included angle is formed between the buffer section 483 and the straight line section 482. The materials 5 are buffered by the buffer sections 483 extending downwards in an inclined manner, so that the materials 5 are prevented from directly impacting objects below the bearing parts 47, and the service life of the device is prolonged. And the side wall of the receiving part 47 is provided with a baffle 473 at the material passing channel 48 for limiting the material 5 in the material passing channel 48, and the material 5 is prevented from leaking through the baffle 473.

In this embodiment, as shown in fig. 6 and 7, an opening 471 is formed in the upper end surface of the receiving member 47, and the first drive motor 44 is incorporated in the opening 471. So as to reduce the occupied area of the equipment and improve the utilization rate of the air.

Meanwhile, a second rotating disc 49 is arranged below the bearing piece 47, a second driving motor 410 is coaxially connected to the second rotating disc 49, and the second driving motor 410 is connected with the supporting plate 46. The service life of the second rotary disk 49 is increased by the above-mentioned damping section 483. And the second rotary disk 49 is rotated around its center by the second driving motor 410. The axial direction of the second rotary disc 49 is perpendicular to the axial direction of the first rotary disc 43, and a plurality of second accommodating grooves 491 which can receive single materials 5 are arranged on the disc wall of the second rotary disc 49 along the circumferential direction. When the second accommodating groove 491 rotates with the second rotating disc 49 to the discharge port of the material passing channel 48, the second accommodating groove 491 receives the material 5 in the material passing channel 48 and rotates continuously. And the wall of the second rotating disc 49 abuts against the discharge opening of the material passing channel 48. The material 5 falling subsequently is blocked by the wall of the second rotating disc 49, and only when the next second accommodating groove 491 rotates to the discharge port of the material passing channel 48, the next material 5 can enter the second accommodating groove 491 to rotate. Since the first rotary disc 43 has divided the material 5 into a plurality of rows and then the material 5 is conveyed row by row at intervals, the material 5 separated by the second rotary disc 49 is a single material 5.

In a preferred embodiment, the discharge port of the material passing channel 48 is an arc opening 471 which can be attached to the plate wall of the second rotating plate 49, and a side wall of the receiving member 47 in the feeding direction of the second rotating plate 49 is provided with a through groove 472, and the through groove 472 is communicated with the material passing channel 48. The discharge hole through the material passing channel 48 is an arc-shaped opening 471 which can be attached to the disk wall of the second rotating disk 49, so that the subsequent materials 5 are prevented from overflowing from the gap between the material passing channel 48 and the second rotating disk 49.

And as shown in fig. 9, the depth of the second receiving groove 491 is smaller than the height of the material 5, and the length of the through groove 472 is smaller than the height of the material 5. But the length of the through groove 472 plus the depth of the second receiving groove 491 is greater than the height of the material 5. It will be easily understood that when a single material 5 falls into the second rotary disk 49, if the depth of the second receiving groove 491 is greater than the height of the material 5, a portion of the lower end of the next material 5 falls into the second receiving groove 491. Since a part of the next material 5 is in the material passing passage 48 and a part of the next material 5 is in the second accommodating groove 491, the material 5 interferes with the second rotary disk 49 to effect rotation during the rotation of the second rotary disk 49. If the length of the through slots 472 is greater than the height of the material 5. The subsequent material 5 will overflow from the vat. While the depth through the second receiving groove 491 is smaller than the height of the material 5, the length of the through groove 472 is smaller than the height of the material 5, but the length of the through groove 472 plus the depth of the second receiving groove 491 is larger than the height of the material 5. After the material 5 falls into the second holding tank 491, the material exceeds the second holding tank 491, and the subsequent material 5 is prevented from falling into the second holding tank 491. And during rotation, the material 5 rotates away from the receiving member 47 in cooperation with the through groove 472 without interference.

A second conveyer belt is arranged below the second rotating disc 49 for receiving the materials 5 in the second accommodating tank 491 and conveying the materials 5. When the second rotating disc 49 rotates to a certain angle, the material 5 automatically rolls from the second accommodating groove 491 to the second conveying belt under the action of gravity. The tail end of the second conveyer belt is provided with a pushing assembly for pushing the materials 5 on the second conveyer belt to enter the heating furnace body 1. Specifically, the pushing assembly comprises a pushing cylinder and a pushing plate 412, and the pushing plate 412 is connected with the pushing cylinder and pushes the material 5 on the second conveying belt to enter the heating furnace under the action of the pushing cylinder. The chain that is used for carrying material 5 is arranged in the heating furnace, and the material 5 that is pushed into the heating furnace body 1 by the pushing assembly is received through the chain and is carried.

It will be readily appreciated that if the materials 5 are delivered at spaced intervals, subsequent materials 5 move to the pushing position of the second conveyor belt as the pusher plate 412 pushes the materials 5 into the warming oven. When push cylinder drives push pedal 412 and moves back, push pedal 412 will touch material 5 on the promotion position, takes place to interfere, and material 5 will promote towards opposite direction, leads to the waste of material 5, and the cylinder also feeds easily and leads to damaging. And the materials 5 are stacked and enter the heating furnace, the materials 5 are mutually contacted, and the contacted parts cannot be fully heated. In the scheme, the materials 5 are divided into a plurality of rows by the first rotating disc 43 before entering the heating furnace, and the materials 5 are conveyed at intervals row by row. And then the materials 5 in the same column are divided into a plurality of rows by the second rotating disc 49, and the materials 5 are conveyed to the second conveying belt one by one, so that the problem that the push plate 412 interferes with the subsequent materials 5 is avoided. And the materials 5 which finally enter the heating furnace one by one to be heated. Avoid appearing a plurality of materials 5 and piling up the simultaneous heating and lead to the insufficient problem of heating. So that the material 5 is heated more fully and more uniformly after entering the heating furnace.

In this embodiment, an arc-shaped plate 413 is connected to the push plate 412. When the pushing cylinder drives the pushing plate 412 to push the material 5 on the second conveying belt, the arc-shaped plate 413 moves to one side of the second rotating disc 49, and the inner arc surface of the arc-shaped plate 413 is attached to the disc wall of the second rotating disc 49 to limit the material 5 in the second rotating disc 49. When the push cylinder drives the push plate 412 to reset, the arc-shaped plate 413 is far away from the second rotating disc 49. Because the timing that the push cylinder pushes the push plate 412 and the material 5 fall into the second conveyor belt (i.e. the rotation speed of the second rotating disc 49) are difficult to achieve complete synchronization, after the device is operated for a long time, the material 5 falls into the second conveyor belt and is conveyed to the pushing position, but the push plate 412 still pushes to cause the problem of interference. In this scheme, when the push pedal 412 promoted material 5 and got into the stove of heating, the arc 413 removed the one side of second rolling disc 49 and forms spacingly to material 5 in the second rolling disc 49, prevents that material 5 from falling out, only under material 5 rotated to second rolling disc 49, just can fall on the second conveyer belt, postpones the time that next material 5 removed the promotion position, avoids taking place to interfere. When the second rotating disc 49 rotates to the position where the material 5 can fall on the second conveyor belt and the push plate 412 does not push, the material 5 directly falls on the second conveyor belt, so that the time for moving the next material 5 to the pushing position is shortened, and the interference is avoided.

In addition, the scheme also comprises a controller, a third driving motor and a temperature sensor. The temperature sensor is arranged on the heating furnace body 1, and the third driving motor is connected with the chain to drive the chain to run. And the third driving motor and the temperature sensor are respectively connected with the controller. When the temperature sensor detects that the temperature of the materials in the heating furnace body 1 on the chain is lower than a preset value, the third driving motor is controlled by the controller to drive the chain to run at a reduced speed. The structure and driving method of the heating device, the third driving motor and the chain in the heating furnace body 1 are conventional devices and common knowledge, and therefore, will not be described in detail herein. The specific process of detecting the temperature of the material in the heating furnace body 1 on the chain by the temperature sensor can refer to the steel-pushing type natural gas forging heating furnace with the application number of 201310570040.5.

The present invention and its embodiments have been described above schematically, and the description is not limited thereto, 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 of the present invention, without departing from the inventive spirit of the present invention, the person skilled in the art should also design the similar structural modes and embodiments without creativity to the technical solution, and all shall fall within the protection scope of the present invention.

Claims (10)

1. An automatic heating furnace is characterized by comprising a heating furnace body, wherein a feeding device is arranged at the front end of a furnace inlet of the heating furnace body; the loading attachment includes horizontal conveying mechanism, horizontal conveying mechanism includes:

the supporting seat is provided with a supporting plate and a first conveying belt for receiving materials and conveying the materials;

the first rotating disc is positioned at the tail end of the first conveying belt, is coaxially connected with a first driving motor and rotates around the center of a circle of the first driving motor;

the first containing grooves are uniformly distributed on the first rotating disc along the circumferential direction, and when the first containing grooves rotate to the first conveying belt along with the first rotating disc, the first containing grooves can contain materials on the first conveying belt and rotate continuously;

the bearing piece is positioned below the first rotating disc and fixedly connected with the supporting plate, and provides bottom support for the first rotating disc and materials in the first accommodating groove; the bearing piece is provided with a material passing channel penetrating through the upper end surface and the lower end surface of the bearing piece, and when the first accommodating tank accommodating materials rotates to the position above the material passing channel, the materials fall into the material passing channel;

the second rotating disc is positioned below the bearing piece, and a second driving motor connected with the supporting plate is coaxially connected to the second rotating disc and rotates around the circle center of the second rotating disc under the action of the second driving motor; the axial direction of the second rotating disc is perpendicular to the axial direction of the first rotating disc, a plurality of second accommodating grooves capable of accommodating single materials are formed in the disc wall of the second rotating disc along the circumferential direction, the disc wall of the second rotating disc abuts against a discharge port of the material passing channel, and when the second accommodating grooves rotate to the discharge port of the material passing channel, the second accommodating grooves accommodate the materials in the material passing channel and rotate continuously;

the second conveying belt is positioned below the second rotating disc and used for receiving materials in the second accommodating groove and conveying the materials;

the pushing assembly is arranged at the tail end of the second conveying belt and used for pushing the materials on the second conveying belt to enter the heating furnace body; the chain that is used for carrying the material is arranged in the heating furnace body, and the material that is pushed into the heating furnace body by the pushing assembly is accepted and carried by the chain.

2. The automatic heating furnace of claim 1, wherein the discharge port of the material passing channel is an arc opening capable of fitting with the plate wall of the second rotating plate, a through groove is formed in the side wall of the receiving piece in the feeding direction of the second rotating plate, the through groove is communicated with the material passing channel, the depth of the second accommodating groove is smaller than the height of the material, the length of the through groove is smaller than the height of the material, and the length of the through groove plus the depth of the second accommodating groove is larger than the height of the material.

3. The automatic heating furnace as claimed in claim 1, wherein a baffle plate for limiting the material in the material passing channel is arranged on the side wall of the receiving member at the material passing channel.

4. The automatic heating furnace of claim 1, wherein the material passing channel is divided into a diameter reduction section, a straight section and a buffer section from top to bottom, the inner diameter of the material passing channel at the upper end of the diameter reduction section is larger than the inner diameter of the material passing channel at the lower end of the diameter reduction section, the inner diameter of the material passing channel at the straight section is the same as the inner diameter of the lower end of the diameter reduction section, and the material passing channel can only contain one material; the material passing channel extends downwards in the buffer section in an inclined mode, and an included angle is formed between the buffer section and the straight line section.

5. The automatic heating furnace of claim 1, wherein the pushing assembly comprises a pushing cylinder and a pushing plate, the pushing plate is connected with the pushing cylinder and pushes the material on the second conveying belt into the heating furnace body under the action of the pushing cylinder; the pushing cylinder drives the pushing plate to push the materials on the second conveying belt, and the arc plate moves to one side of the second rotating disc to limit the materials in the second rotating disc; when the pushing cylinder drives the push plate to reset, the arc-shaped plate is far away from the second rotating disc.

6. The automatic heating furnace of claim 1, wherein the first conveyor belt is provided with limiting plates at two sides, and the limiting plates at two sides of the first conveyor belt are tangent to the first rotating disc.

7. The automatic heating furnace as claimed in claim 1, wherein an upper end surface of the receiving member is provided with an opening, and the first driving motor is accommodated in the opening.

8. The automatic heating furnace of claim 1, wherein the feeding device further comprises a longitudinal conveying mechanism, the longitudinal conveying mechanism comprises a feeding box, a lifting assembly is arranged in the feeding box and comprises a plurality of movable plates, the movable plates are arranged in a stepped manner from low to high in the vertical direction, the height difference between every two adjacent movable plates is larger than the height of the material, the bottoms of the movable plates are fixedly connected through a connecting plate, a lifting cylinder is connected to the bottom end of the connecting plate, a fixing plate is arranged between every two adjacent movable plates, two sides of the fixing plate are fixedly connected with inner walls of two sides of the feeding box, and the upper plate surfaces of the movable plates and the upper plate surface of the fixing plate are inclined planes which extend towards the direction of the highest movable plate and are inclined downwards.

9. The automatic heating furnace according to claim 8, wherein the feeding device further comprises a lifting mechanism, the lifting mechanism comprises a fixed frame and a material carrying vehicle for carrying the material, a guide rail is arranged on the fixed frame along the height direction of the fixed frame, a pulley is slidably arranged on the guide rail, and the pulley is connected with the material carrying vehicle; the upper end of the fixed frame is provided with an electric hoist, and the electric hoist is connected with the material carrying vehicle through a connecting rod so as to drive the material carrying vehicle to do lifting action along a guide rail; and the guide rail is divided into a linear guide rail and a bent guide rail from bottom to top, and after the material carrying vehicle enters the bent guide rail, the material carrying vehicle dumps towards the feed inlet of the feed box.

10. The automatic heating furnace of claim 1, further comprising a controller, a third driving motor, and a temperature sensor, wherein the temperature sensor is disposed on the heating furnace body, the third driving motor is connected to the chain to drive the chain to operate, the third driving motor and the temperature sensor are respectively connected to the controller, and the temperature sensor detects that the temperature of the material on the chain in the heating furnace body is lower than a preset value, and then controls the third driving motor to drive the chain to operate at a reduced speed.

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