阅读说明：本技术 一种用于物料反应的输送装置及网带加热炉 (Conveying device for material reaction and mesh belt heating furnace ) 是由 张冠炜 梁可 黄俊衡 周健泉 于 2021-09-10 设计创作，主要内容包括：本申请公开了一种用于物料反应的输送装置及网带加热炉,涉及加热设备技术领域,其中网带加热炉包括输送装置；输送装置包括网带以及驱动机构；驱动机构与网带连接,用于带动网带运动；还包括软带；软带安装于网带上,且与网带同步运动,用于隔离物料与网带的接触；网带上于两侧边缘位置分别设有第一挡边部；软带的两侧边缘位置分别贴合第一挡边部并弯折形成第二挡边部。通过这一结构设计,可以直接在软带上布料,布料方便,布料厚度容易控制,布料均匀性好,从而受热一致性好。由于软带是连续的,位于网带的上部分的软带均可用于布料,进而较大地增加了产能,也随之降低了能耗,而且生产连续性好,适用于大规模的生产。(The application discloses a conveying device for material reaction and a mesh belt heating furnace, and relates to the technical field of heating equipment, wherein the mesh belt heating furnace comprises a conveying device; the conveying device comprises a mesh belt and a driving mechanism; the driving mechanism is connected with the mesh belt and is used for driving the mesh belt to move; also comprises a soft belt; the soft belt is arranged on the mesh belt, moves synchronously with the mesh belt and is used for isolating the contact of the materials and the mesh belt; the net belt is provided with first edge blocking parts at the edge positions of two sides respectively; the edge positions of two sides of the soft belt are respectively attached to the first edge retaining part and bent to form a second edge retaining part. Through the structural design, the soft belt can be directly coated with cloth, the cloth is convenient, the thickness of the cloth is easy to control, the uniformity of the cloth is good, and the heating consistency is good. Because the soft belt is continuous, the soft belt positioned at the upper part of the mesh belt can be used for distributing materials, thereby greatly increasing the productivity, reducing the energy consumption, having good production continuity and being suitable for large-scale production.)

1. A conveying device for material reaction comprises a mesh belt and a driving mechanism;

the driving mechanism is connected with the mesh belt and is used for driving the mesh belt to move;

it is characterized by also comprising a soft belt;

the soft belt is arranged on the mesh belt, moves synchronously with the mesh belt and is used for isolating materials from being in contact with the mesh belt;

the net belt is provided with first edge blocking parts at the edge positions of two sides respectively;

and the edge positions of two sides of the soft belt are respectively attached to the first edge retaining part and bent to form a second edge retaining part.

2. The conveying device for material reaction according to claim 1, wherein two side edges of the mesh belt are bent to form the first edge retaining part.

3. The conveying device for material reaction according to claim 1, wherein the soft belt is integrally connected with the mesh belt or detachably connected with the mesh belt.

4. A conveyor for material reactions as in claim 3 wherein the drive mechanism includes a drive roller, a driven roller and a first drive motor;

the first driving motor is connected with the driving roller and used for driving the driving roller to rotate;

the mesh belt is sleeved on the driving roller and the driven roller and is in transmission connection with the driving roller and the driven roller respectively.

5. The conveying device for material reaction according to claim 1, further comprising a plurality of first supporting rollers and supporting roller drivers;

the first supporting rollers are arranged in an array and used for supporting the upper part of the mesh belt;

the supporting roller drivers are used for driving the first supporting rollers to rotate and assisting in driving the mesh belt to move.

6. A conveyor for material reaction as claimed in claim 3 wherein said flexible belt is integrally connected to said mesh belt;

the device also comprises a plurality of second supporting rollers;

and the second supporting rollers are arranged in an array and used for supporting the lower part of the mesh belt.

7. A conveyor for material reaction as claimed in claim 3 wherein said flexible belt is detachably connected to said mesh belt;

the device also comprises a plurality of second supporting rollers and a plurality of third supporting rollers;

the second supporting rollers are arranged in an array and used for supporting the lower part of the mesh belt;

and the third supporting rollers are arranged in an array and positioned below the second supporting rollers and are used for supporting the lower part of the soft belt.

8. The conveying device for material reaction according to claim 4, wherein the soft belt is integrally connected with the mesh belt;

the device also comprises a plurality of first guide rollers;

and the first guide rollers are arranged at the lower position between the driving roller and the transmission roller and used for guiding the lower part of the mesh belt.

9. The conveying device for material reaction according to claim 4, wherein the soft belt is detachably connected with the mesh belt;

the device also comprises a plurality of first guide rollers and a plurality of second guide rollers;

the first guide rollers are arranged at the lower position between the driving roller and the transmission roller and used for guiding the lower part of the mesh belt;

and the second guide rollers are arranged at the positions below the first guide rollers and are used for guiding the lower parts of the soft belts.

10. A mesh belt heating furnace comprising the conveyor for material reaction of any one of claims 1 to 9.

Technical Field

The application relates to the technical field of heating equipment, in particular to a conveying device for material reaction and a mesh belt heating furnace.

Background

The existing heating furnace device has the advantages that reaction materials are placed in a tray, the reaction materials are brought into a furnace body through a mesh belt to be heated and react, and the tray is taken out of the furnace body and then is recycled, so that the material heating reaction process is completed. This process of transporting materials to react still has some disadvantages: 1, the tray can contain limited materials, so that the capacity is low and the energy consumption is high; 2, the tray is inconvenient to distribute, so that the heated consistency is poor due to uneven material thickness; 3, when in use, a system for distributing the tray, feeding and recovering the tray needs to be additionally arranged, so that the equipment installation and maintenance cost is high.

Disclosure of Invention

In view of this, the present application aims to provide a conveying device and a mesh belt heating furnace for material reaction, which solve some disadvantages of the existing heating furnace devices.

In order to achieve the technical purpose, the application provides a conveying device for material reaction, which comprises a mesh belt and a driving mechanism;

the driving mechanism is connected with the mesh belt and is used for driving the mesh belt to move;

also comprises a soft belt;

the soft belt is arranged on the mesh belt, moves synchronously with the mesh belt and is used for isolating materials from being in contact with the mesh belt;

the net belt is provided with first edge blocking parts at the edge positions of two sides respectively;

and the edge positions of two sides of the soft belt are respectively attached to the first edge retaining part and bent to form a second edge retaining part.

Furthermore, the edges of two sides of the mesh belt are bent to form the first edge blocking part.

Further, the soft belt is integrally connected with the mesh belt or detachably connected with the mesh belt.

Further, the driving mechanism comprises a driving roller, a driven roller and a first driving motor;

the first driving motor is connected with the driving roller and used for driving the driving roller to rotate;

the mesh belt is sleeved on the driving roller and the driven roller and is in transmission connection with the driving roller and the driven roller respectively.

Further, the device also comprises a plurality of first supporting rollers and a supporting roller driver;

the first supporting rollers are arranged in an array and used for supporting the upper part of the mesh belt;

the supporting roller drivers are used for driving the first supporting rollers to rotate and assisting in driving the mesh belt to move.

Further, the soft belt is integrally connected with the mesh belt;

the device also comprises a plurality of second supporting rollers;

and the second supporting rollers are arranged in an array and used for supporting the lower part of the mesh belt.

Further, the soft belt is detachably connected with the mesh belt;

the device also comprises a plurality of second supporting rollers and a plurality of third supporting rollers;

the second supporting rollers are arranged in an array and used for supporting the lower part of the mesh belt;

and the third supporting rollers are arranged in an array and positioned below the second supporting rollers and are used for supporting the lower part of the soft belt.

Further, the soft belt is integrally connected with the mesh belt;

the device also comprises a plurality of first guide rollers;

and the first guide rollers are arranged at the lower position between the driving roller and the transmission roller and used for guiding the lower part of the mesh belt.

Further, the soft belt is detachably connected with the mesh belt;

the device also comprises a plurality of first guide rollers and a plurality of second guide rollers;

the first guide rollers are arranged at the lower position between the driving roller and the transmission roller and used for guiding the lower part of the mesh belt;

and the second guide rollers are arranged at the positions below the first guide rollers and are used for guiding the lower parts of the soft belts.

The application also discloses a mesh belt heating furnace, which comprises the conveying device for material reaction.

According to the technical scheme, the conveying device for material reaction is additionally provided with the high-temperature-resistant and corrosion-resistant soft belt, the soft belt is installed on the mesh belt in a closed mode and moves synchronously with the mesh belt, materials are borne, isolation between the materials and the mesh belt is achieved, and the mesh belt is prevented from being corroded by the materials. And, be equipped with first flange portion respectively in both sides border position on the guipure to make the both sides border position of soft area laminate first flange portion respectively and buckle and form second flange portion, when utilizing soft area to lay the material like this, can be better enclose the fender to the material, avoid the material outflow. Through the structural design, the soft belt can be directly distributed, so that the distribution of materials is convenient, the thickness of the distribution is easy to control, the uniformity of the distribution is good, and the heating consistency is good. Because the soft belt is continuous, the soft belt positioned at the upper part of the mesh belt can be used for distributing materials, thereby greatly increasing the productivity, reducing the energy consumption, having good production continuity and being suitable for large-scale production. In addition, the distribution and the discharge of the materials are easier to realize, the complexity of the equipment is reduced, and the installation and maintenance cost of the equipment is reduced.

According to the technical scheme, the mesh belt heating furnace provided by the application has the same beneficial effects as the improved conveying device.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without inventive exercise.

FIG. 1 is a schematic partial view of a conveyor for reacting materials provided herein;

FIG. 2 is a cross-sectional view of a belt furnace provided in the present application with the flexible belt detachably connected to the belt;

FIG. 3 is a front view of a mesh belt furnace provided in the present application with the soft belt detachably connected to the mesh belt;

FIG. 4 is a front view of a mesh belt heating furnace provided in the present application in a case where a soft belt and a mesh belt are integrally connectable;

in the figure: 1. a soft belt; 2. a mesh belt; 3. a first support roller; 4. a second support roller; 5. a third support roller; 6. a heating device; 7. a furnace body; 8. a tail gas exhaust device; 9. a temperature measuring device; 10. a furnace frame; 11. material preparation; 12. a drive roll; 13. a driven roller; 14. a feeding processing device; 15. a discharge processing device; 16. a first guide roller; 17. a second guide roller; 18. a first drive motor; 101. a second bead; 201. a first flange portion; 301. supporting the roller drive.

Detailed Description

The technical solutions of the embodiments of the present application will be described clearly and completely with reference to the accompanying drawings, and it is obvious that the described embodiments are some, but not all, of the embodiments of the present application. All other embodiments obtained by a person of ordinary skill in the art based on the embodiments in the present application without any creative effort belong to the protection scope of the embodiments in the present application.

In the description of the embodiments of the present application, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "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 in describing the embodiments of the present application and simplifying the description, but do not indicate or imply that the referred devices or elements must have specific orientations, be configured in specific orientations, and operate, and thus, should not be construed as limiting the embodiments of the present application. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the embodiments of the present application, it should be noted that the terms "mounted," "connected," and "connected" are used broadly and are defined as, for example, a fixed connection, an exchangeable connection, an integrated connection, a mechanical connection, an electrical connection, a direct connection, an indirect connection through an intermediate medium, and a communication between two elements, unless otherwise explicitly stated or limited. Specific meanings of the above terms in the embodiments of the present application can be understood in specific cases by those of ordinary skill in the art.

The embodiment of the application discloses a conveying device and a mesh belt heating furnace for material reaction.

Referring to fig. 1, an embodiment of a conveying device for material reaction provided in an embodiment of the present application includes:

a mesh belt 2 and a drive mechanism. The mesh belt 2 may be a conventional metal mesh belt 2, which will not be described in detail. The driving mechanism is connected with the mesh belt 2 and used for driving the mesh belt 2 to move, and at least the upper part of the mesh belt 2 penetrates through the heating cavity of the furnace body 7, so that the materials 11 can be conveyed to pass through the furnace body 7 for heating reaction.

Still include soft area 1, with soft area 1 closed installation on guipure 2, and with guipure 2 synchronous motion for keep apart the contact of material 11 with guipure 2, realized the isolation between material 11 and the guipure 2, avoid guipure 2 to be corroded by material 11. The soft belt 1 may be made of a high temperature resistant and corrosion resistant material, has sufficient compactness, can be used for bearing the material 11, and can realize the isolation between the material 11 and the mesh belt 2, and specifically may be made of glass fiber, polyvinyl chloride and other materials without limitation.

Be equipped with first flange portion 201 respectively in both sides border position on guipure 2, the first flange portion 201 of laminating respectively and bending type formation second flange portion 101 are taken in both sides border position of soft area 1, and soft area 1 utilizes the compliance of self, and direct laminating can be buckled type formation second flange portion in first flange portion 201 leaf to become the portion through first fender and support, realize keeping off enclosing of the material 11 of laying on soft area 1, avoid material 11 to flow outward.

Through the structural design, the cloth can be directly distributed on the soft belt 1, so that the material 11 is convenient to distribute, the thickness of the cloth is easy to control, the uniformity of the cloth is good, and the heating consistency is good. Because the soft belt 1 is continuous, the soft belt 1 positioned at the upper part of the mesh belt 2 can be used for distributing materials, thereby greatly increasing the productivity and reducing the energy consumption, and the production continuity is good, thus being suitable for large-scale production. In addition, the material distribution and the material discharge of the material 11 are easier to realize, the equipment complexity is reduced, and the equipment installation and maintenance cost is reduced.

The above is a first embodiment of a conveying device for material reaction provided in the embodiments of the present application, and the following is a second embodiment of a conveying device for material reaction provided in the embodiments of the present application, please refer to fig. 1 to 4 specifically.

The scheme based on the first embodiment is as follows:

further, as shown in fig. 1, the two side edges of the mesh belt 2 may be directly bent, and the bending angles may be adjusted according to actual needs, so as to form the first flange portions 201 respectively. Wherein, two first flange portions 201 can be the slope setting to the space that forms between toward keeping away from guipure 2 direction and narrowing gradually, and then can guarantee to play better fender that encloses to material 11, do not do the restriction specifically.

Further, as shown in fig. 3 and 4, the connection of the soft belt 1 and the mesh belt 2 may be integrally connected or detachably connected. The integral connection can be realized by directly sewing the soft belt 1 on the mesh belt 2 by means of sewing, and the separable connection can be realized by directly laying the soft belt 1 on the mesh belt 2 and keeping the soft belt 1 and the mesh belt 2 to move together.

Further, the drive mechanism includes, in terms of structural composition, a drive roller 12, a driven roller 13, and a first drive motor 18. The first driving motor 18 is connected with the driving roller 12 and used for driving the driving roller 12 to rotate, and the mesh belt 2 is sleeved on the driving roller 12 and the driven roller 13 and is in transmission connection with the driving roller 12 and the driven roller 13 respectively. The transmission connection between the first driving motor 18 and the driving roller 12 may be a belt transmission, a chain transmission, etc., and the transmission cooperation between the driving roller 12, the driven roller 13 and the mesh belt 2 may be a chain transmission, a gear transmission, etc., and is not limited in particular.

Further, a number of first support rollers 3 and support roller drivers 301 are included. The first supporting rollers 3 are arranged in an array and used for supporting the upper part of the mesh belt 2, and the supporting roller driver 301 is used for driving each first supporting roller 3 to rotate and used for assisting in driving the mesh belt 2 to move. The supporting roller driver 301 may be composed of a plurality of second driving motors corresponding to the first supporting rollers 3 one by one, and respectively connected to the first supporting rollers 3, or may be composed of only one second driving motor and a transmission assembly, and each first supporting roller 3 is connected to one driving motor through the transmission assembly, so that the plurality of first supporting rollers 3 are driven by one driving motor to move. The number and the gap of the first supporting rollers 3 can be selected according to actual needs without limitation. Through increasing the first supporting roller 3 that sets up to have the power, can make guipure 2 reduce greatly by the pulling force of initiative roller 12 for guipure 2's atress is more even, improves guipure 2's life.

Further, as shown in fig. 3, the soft belt 1 is integrally connected with the mesh belt 2, and the soft belt further comprises a plurality of second supporting rollers 4, and the plurality of second supporting rollers 4 are arranged in an array and used for supporting the lower part of the mesh belt 2.

Further, as shown in fig. 2, taking the example that the soft belt 1 is separably connected with the mesh belt 2, the soft belt further includes a plurality of second supporting rollers 4 and a plurality of third supporting rollers 5, the plurality of second supporting rollers 4 are arranged in an array and are used for supporting the lower portion of the mesh belt 2, and the plurality of third supporting rollers 5 are arranged in an array and are located below the second supporting rollers 4 and are used for supporting the lower portion of the soft belt 1.

Further, as shown in fig. 4, for example, the soft belt 1 is integrally connected to the mesh belt 2, and a plurality of first guide rollers 16 may be further included. A plurality of first guide rollers 16 are provided outside the heating chamber at a lower position between the drive roller 12 and the driving roller for guiding the lower portion of the mesh belt 2.

Further, as shown in fig. 3, taking the example of the detachable connection of the soft belt 1 and the mesh belt 2, a plurality of second guide rollers 17 are provided in addition to the plurality of first guide rollers 16. A plurality of first guide rollers 16 are provided at a lower position between the drive roller 12 and the driving roller for guiding the lower portion of the mesh belt 2, and a plurality of second guide rollers 17 are provided at a lower position of the first guide rollers 16 for guiding the lower portion of the soft belt 1.

As shown in fig. 2 to 4, the present application further discloses a mesh belt heating furnace, which includes the conveying device of the first embodiment or the second embodiment. The structure of the furnace body 7 of the mesh belt heating furnace can be designed according to a conventional heating furnace, and corresponding heat insulating materials and the like are coated or filled, and detailed description is omitted. The furnace body 7 is specifically arranged on a furnace frame 10, the furnace frame 10 is used for supporting and fixing the furnace body 7, and at least the upper part of the mesh belt 2 penetrates through a heating cavity of the furnace body 7 to ensure that the material 11 can be conveyed to pass through the furnace body 7 for heating reaction. The mesh belt heating furnace also comprises a tail gas exhaust device 8 which is arranged at the top of the furnace body 7; the temperature measuring device 9 is arranged on the furnace body 7 and used for measuring the temperature in the installation cavity; the heating device 6 is arranged in the heating cavity, is positioned above the mesh belt 2 and is used for heating the material 11; the feeding processing device 14 is arranged at the feeding end of the mesh belt 2 and used for distributing the materials 11 on the soft belt 1; and the discharge processing device 15 is installed at the discharge end position of the mesh belt 2 and is used for recovering the material 11 after the heating reaction, which is not described in detail.

Further, the driving roller 12 and the driven roller 13 are respectively installed outside the openings at both ends of the heating cavity, and can be respectively installed and fixed by corresponding installation frames, or installed on the furnace frame 10 without limitation.

Further, the upper portion of the mesh belt 2 passes through the heating chamber and the lower portion of the mesh belt 2 passes through the hob 10. Of course, it is also possible that both the upper portion and the lower portion pass through the heating chamber, that is, the entire mesh belt passes directly through the heating chamber, and the arrangement is not particularly limited.

Further, taking the soft belt 1 and the mesh belt 2 integrally connected as an example, the first guide roller 16 is disposed outside the heating cavity and below the position between the driving roller 12 and the driving roller, and is used for guiding the lower portion of the mesh belt 2, specifically, the lower portion of the mesh belt 2 to pass through the furnace frame 10.

Further, taking the example that the soft belt 1 is separably connected with the mesh belt 2, a plurality of first guide rollers 16 are arranged outside the heating cavity and below the position between the driving roller 12 and the driving roller for guiding the lower part of the mesh belt 2, and a plurality of second guide rollers 17 are arranged outside the heating cavity and below the first guide rollers 16 for guiding the lower part of the soft belt 1.

Further, a plurality of first support rollers 3 are arranged in an array in the heating chamber for supporting the upper portion of the mesh belt 2.

Further, taking the soft belt 1 and the mesh belt 2 as an example, a plurality of second support rollers 4 are arranged outside the heating cavity in an array manner for supporting the lower part of the mesh belt 2.

Further, taking the example that the soft belt 1 is separably connected with the mesh belt 2, a plurality of second support rollers 4 are arranged outside the heating cavity in an array manner and used for supporting the lower part of the mesh belt 2, and a plurality of third support rollers 5 are arranged outside the heating cavity in an array manner and located below the second support rollers 4 and used for supporting the lower part of the soft belt 1.

While the present application has been described in detail with reference to the preferred embodiments and applications, it will be apparent to those skilled in the art that the present invention is not limited to the disclosed embodiments and applications.