A carbon conversion reformer
By introducing an opening and closing stabilizing mechanism into the carbon conversion furnace, the inconvenience of operation caused by bolted connections has been solved, and the furnace door can be stably plugged in and positioned, thus improving maintenance efficiency.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Filing Date
- 2025-08-20
- Publication Date
- 2026-07-14
AI Technical Summary
In existing carbon conversion furnaces, the furnace door is connected to the furnace body by bolts, which makes opening and closing inconvenient and affects maintenance efficiency.
An opening and closing stabilizing mechanism is adopted, including a stabilizing groove, a stabilizing column, a translational support mechanism, and an insert cylinder, to achieve stable insertion and positioning between the furnace door and the converter, avoiding bolt operation.
This improves the convenience and efficiency of furnace maintenance and operation, ensures the stability of furnace door closure, and avoids the cumbersome bolt operation.
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Figure CN224485979U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of carbon conversion furnace technology, and more specifically, to a carbon conversion furnace. Background Technology
[0002] The core equipment for achieving efficient conversion and recycling of carbon resources is widely used in coal chemical industry, environmental protection, energy and other fields. It aims to convert carbon-containing raw materials into high-value products through chemical reactions. The carbon conversion furnace drives the chemical bonds of carbon-containing raw materials to break and recombine through precise control of temperature, pressure and reaction atmosphere. Under high temperature or catalyst, carbon raw material molecules are activated and converted into target products such as syngas through reforming, gasification and other reactions. The heating system provides energy to maintain the reaction conditions. The products are separated and purified before being output. It not only realizes the transformation and efficient utilization of carbon resources, but also reduces carbon emissions. It has the dual value of environmental protection and energy production. Since ash and other impurities will adhere to the inside of the furnace during operation, it is necessary to carry out treatment operations.
[0003] In related technologies, during the use of a converter, a furnace door is typically installed on the surface of the furnace body to provide workers with space to enter the furnace and perform ash and slag processing operations.
[0004] However, in the current use of converters, the furnace door and furnace body are mainly connected and fixed by bolts. However, the bolt connection process requires the operation of multiple bolts, and the tightness of multiple bolts is not easy to be consistent, which makes the opening and closing of the furnace door inconvenient and affects the convenience and efficiency of the converter's maintenance and operation. Utility Model Content
[0005] To overcome the above deficiencies, this utility model provides a carbon conversion furnace that overcomes or at least partially solves the above technical problems.
[0006] This utility model is implemented as follows:
[0007] This utility model provides a carbon conversion furnace, including a conversion furnace, with supports installed on both sides of the front side of the conversion furnace, and a furnace door installed on the inner side of the supports;
[0008] The opening and closing stabilizing mechanism includes:
[0009] Stabilizing groove; the stabilizing groove is located on the left side of the furnace door, and the left side of the support has a stabilizing opening that communicates with the stabilizing groove;
[0010] Stabilizing column; the stabilizing column is movably connected inside the stabilizing groove and the stabilizing opening, and a stabilizing plate located on the left side of the support is fixedly connected to the left side of the stabilizing column;
[0011] Translational support mechanism; the translational support mechanism is located on the left side of the stabilizing plate.
[0012] In a preferred embodiment, the translation support mechanism includes a translation port, a support rod, and a support plate. The translation port is located on the left side of the stabilizing plate. The support rod is movably connected inside the translation port. The right side of the support rod is fixedly connected to the left side of the support. The support plate is fixedly connected to the left side of the support rod by bolts.
[0013] In a preferred embodiment, a plug cylinder communicating with a translation port is fixedly connected to the top left side of the stabilizing plate, and a plug rod is movably connected inside the plug cylinder.
[0014] In a preferred embodiment, a slot communicating with the insert is provided on the right side of the top of the support rod, and the bottom of the insert is located inside the slot.
[0015] In a preferred embodiment, the front side of the insert rod is provided with a groove, and the top of the front side of the insert cylinder is threadedly connected to a sliding bolt located inside the groove.
[0016] In a preferred embodiment, the front side of the support is movably connected to a card holder located on the left side of the furnace door, and the front side of the right side of the card holder is fixedly connected to a rotating handle.
[0017] In a preferred embodiment, a magnetic suction plate is embedded and connected to the left side of the front side of the furnace door, and a magnetic plate magnetically connected to the magnetic suction plate is embedded and connected to the right side of the rear side of the card holder.
[0018] In a preferred embodiment, the front side of the support is provided with a threaded groove, and the internal thread of the threaded groove is connected to a stud located inside the bracket.
[0019] The carbon conversion furnace provided by this utility model has the following beneficial effects:
[0020] 1. By setting up an opening and closing stabilizing mechanism, the connection between the flipped furnace door and the converter can be stabilized, so that the staff can close and stabilize the furnace door after opening and closing the converter. This avoids the need to repeatedly operate multiple bolts during the use of the furnace door, thus improving the convenience and efficiency of the converter maintenance operation.
[0021] 2. By setting up a translation support mechanism, the stabilizing plate can perform translation support and guidance work between the stabilizing column and the support during the movement operation, so that the user can easily translate the stabilizing rod to drive the stabilizing column for operation, avoiding the separation or displacement of the stabilizing plate from the support during use, thus improving the ease of operation and stability of the stabilizing plate and stabilizing column.
[0022] 3. By setting up inserts and rods, the stabilizing column and the support can be connected and positioned during operation using a stabilizing plate and a support rod. This avoids the difficulty in positioning the stabilizing column during use, thus improving the working stability of the stabilizing column. Attached Figure Description
[0023] To more clearly illustrate the technical solutions of the embodiments of this utility model, the drawings used in the embodiments will be briefly introduced below. It should be understood that the following drawings only show some embodiments of this utility model and should not be regarded as a limitation of the scope. For those skilled in the art, other related drawings can be obtained from these drawings without creative effort.
[0024] Figure 1 This is an overall perspective view provided by an embodiment of the present utility model;
[0025] Figure 2 A schematic diagram of the three-dimensional cross-sectional structure of the furnace door provided for an embodiment of this utility model;
[0026] Figure 3 A partial three-dimensional cross-sectional structural diagram of the stabilizing plate provided for an embodiment of this utility model;
[0027] Figure 4 A partial three-dimensional cross-sectional structural diagram of the support provided for an embodiment of this utility model;
[0028] In the diagram: 1. Converter; 2. Support; 3. Furnace door; 4. Stabilizing groove; 5. Stabilizing port; 6. Stabilizing column; 7. Stabilizing plate; 8. Shifting port; 9. Support rod; 10. Support plate; 11. Insert cylinder; 12. Insert rod; 13. Slot; 14. Slide groove; 15. Slide bolt; 16. Card holder; 17. Rotary handle; 18. Magnetic suction plate; 19. Magnetic plate; 20. Screw groove; 21. Screw. Detailed Implementation
[0029] To make the objectives, technical solutions, and advantages of the embodiments of this utility model clearer, the technical solutions of the embodiments of this utility model will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of this utility model, not all embodiments. Based on the embodiments of this utility model, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of this utility model.
[0030] Reference Figures 1-4This utility model provides a technical solution: a carbon conversion furnace, including a conversion furnace 1 and an opening and closing stabilizing mechanism. Supports 2 are installed on both sides of the front side of the conversion furnace 1, and furnace doors 3 are installed on the inner side of the supports 2. The furnace doors 3 can be inserted and stabilized between the furnace doors 3 after being turned over, so that the furnace doors 3 can be closed and stabilized after the furnace doors 1 are opened and cleaned by the staff. This avoids the need to repeatedly operate multiple bolts during the use of the furnace doors 3, thus improving the convenience and efficiency of the maintenance and operation of the conversion furnace 1.
[0031] Reference Figures 1-4 In a preferred embodiment, the opening and closing stabilizing mechanism includes a stabilizing groove 4, which is located on the left side of the furnace door 3. A stabilizing opening 5, communicating with the stabilizing groove 4, is located on the left side of the support 2. A stabilizing column 6 is movably connected inside the stabilizing groove 4 and the stabilizing opening 5. A stabilizing plate 7, located on the left side of the support 2, is fixedly connected to the left side of the stabilizing column 6. A translational support mechanism is located on the left side of the stabilizing plate 7. When the furnace door 3 passes the support 2 on the right side of the converter 1 and flips to close the converter 1, the left side of the furnace door 3 enters the support 2 on the left side of the converter 1. Holding the stabilizing plate 7 moves multiple stabilizing columns 6 to the right, allowing the stabilizing columns 6 to pass through the stabilizing opening 5, penetrate the support 2, and enter the stabilizing groove 4. The support 2 provides a closed and stable connection between the furnace door 3 and the converter 1. The translation support mechanism includes a translation port 8, a support rod 9, and a support plate 10. The translation port 8 is located on the left side of the stabilizing plate 7. The support rod 9 is movably connected inside the translation port 8. The right side of the support rod 9 is fixedly connected to the left side of the support 2. The support plate 10 is fixedly connected to the left side of the support rod 9 by bolts. The stabilizing plate 7 can provide translation support and guidance between the stabilizing column 6 and the support 2 during the movement operation, so that the user can easily move the stabilizing rod to drive the stabilizing column 6 for operation. This avoids the stabilizing plate 7 from separating from or shifting from the support 2 during use, thus improving the ease of operation and stability of the stabilizing plate 7 and the stabilizing column 6.
[0032] Reference Figures 2-3 In a preferred embodiment, a plug 11 connected to the translation port 8 is fixedly connected to the top left side of the stabilizing plate 7. A plug rod 12 is movably connected inside the plug 11. The stabilizing plate 7, in conjunction with the support rod 9, can perform plug-in positioning work between the stabilizing column 6 and the support 2 during operation, thus avoiding the situation where the stabilizing column 6 is difficult to position during use, thereby improving the working stability of the stabilizing column 6. A slot 13 connected to the plug 11 is opened on the right side of the top of the support rod 9. The bottom of the plug rod 12 is located inside the slot 13, which can provide space for the plug rod 12 to apply plug-in force, thus avoiding the situation where the plug rod 12 is difficult to apply plug-in positioning force effectively during use, thereby improving the plug-in force application effect of the plug rod 12.
[0033] Reference Figures 2-4In a preferred embodiment, a groove 14 is provided on the front side of the insertion rod 12, and a sliding bolt 15 located inside the groove 14 is threadedly connected to the top of the front side of the insertion cylinder 11. This can limit the lifting and sliding of the insertion rod 12 and the insertion cylinder 11 to prevent them from separating during use, thus improving the working stability of the insertion rod 12. A bracket 16 located on the left side of the furnace door 3 is movably connected to the front side of the support 2, and a rotating handle 17 is fixedly connected to the front side of the right side of the bracket 16. This can stabilize the support 2 and the furnace door 3 when it is flipped to the left side of the conversion furnace 1, preventing the furnace door 3 from shifting during the stabilization operation and causing the stabilization groove 4 and the stabilization opening 5 to misalign. This improves the operational stability of the furnace door 3.
[0034] Reference Figures 2-4 In a preferred embodiment, a magnetic suction plate 18 is inlaid and connected to the left side of the front side of the furnace door 3, and a magnetic plate 19 magnetically connected to the magnetic suction plate 18 is inlaid and connected to the right side of the rear side of the card holder 16. This allows for magnetic positioning between the card holder and the furnace door 3, preventing the card holder 16 from having difficulty effectively blocking the furnace door 3 during use. This improves the working stability of the card holder 16. A screw groove 20 is provided on the front side of the support 2. The screw groove 20 is internally threaded with a stud 21 located inside the card holder 16. This allows for a rotatable connection between the card holder 16 and the support 2, preventing the card holder 16 from separating from the support 2 during use. This improves the working stability of the card holder 16.
[0035] Specifically, the working process or principle of this carbon conversion furnace is as follows: During use, when personnel open the conversion furnace 1 through the tilting furnace door 3 and process the ash and slag inside the conversion furnace 1, they tilt the furnace door 3. At this time, the support 2 on the right side of the conversion furnace 1 tilts and connects the furnace door 3 to the conversion furnace 1. As the furnace door 3 tilts, the conversion furnace 1 closes, and the left side of the furnace door 3 enters the support 2 on the left side of the conversion furnace 1. Then, by holding the handle 17 and rotating the clamp 16 to the front of the furnace door 3, the magnetic... Plate 19 moves with the card holder 16 and contacts the magnetic suction plate 18 on the front side of the furnace door 3, performing magnetic positioning between the card holder 16 and the furnace door 3. Simultaneously, stud 21 engages with screw groove 20 to rotate and connect the card holder 16 to the support 2, ensuring the card holder 16 remains stable and providing a barrier between the furnace door 3 and the support 2. During this process, the stabilizing groove 4 rotates with the furnace door 3 into the support 2 on the left side of the converter 1. When the card holder 16 blocks the front side of the furnace door 3, it indicates that the stabilizing groove 4 is aligned with the stabilizing opening 5. To prepare for the subsequent entry of the stabilizing column 6 through the stabilizing port 5 and the support 2 into the stabilizing groove 4, the stabilizing plate 7 is then held and moved to the right, causing multiple stabilizing columns 6 to move. At this time, the support rod 9 moves inside the translation port 8, providing translational support and guidance between the stabilizing plate 7 and the support 2, allowing the stabilizing column 6 to pass through the stabilizing port 5 and the support 2 into the stabilizing groove 4. This facilitates the stabilizing column 6's insertion and stabilization of the furnace door 3 and the converter 1 after the furnace door is closed. At this time, the inserting cylinder 11 drives the inserting rod 12 to follow the stabilizing plate. 7. Move to the right. When the stabilizing column 6 is fully inside the stabilizing groove 4, it means that the insertion rod 12 is aligned with the slot 13. At this time, the insertion rod 12 moves downward under its own weight and enters the slot 13. The support rod 9 performs the insertion and positioning work between the stabilizing plate 7, the stabilizing column 6 and the support 2 during operation. This causes the stabilizing column 6 to be stably inserted and positioned between the furnace door 3 and the converter 1 through the support 2. At the same time, the sliding bolt 15 moves inside the sliding groove 14 to prepare for the subsequent upward restriction of the insertion rod 12.
[0036] It should be noted that the converter 1, support 2 and furnace door 3 are all existing devices or equipment, or devices or equipment that can be implemented with existing technology. Their power supply, specific composition and principle are clear to those skilled in the art, so they will not be described in detail.
Claims
1. A carbon conversion furnace, comprising a conversion furnace (1), wherein supports (2) are installed on both sides of the front side of the conversion furnace (1), and a furnace door (3) is installed on the inner side of the supports (2), characterized in that... ; The opening and closing stabilizing mechanism includes: Stabilizing groove (4); the stabilizing groove (4) is opened on the left side of the furnace door (3), and the left side of the support (2) is provided with a stabilizing port (5) that communicates with the stabilizing groove (4); Stabilizing column (6); The stabilizing column (6) is movably connected inside the stabilizing groove (4) and the stabilizing port (5), and the left side of the stabilizing column (6) is fixedly connected to the stabilizing plate (7) located on the left side of the support (2); Translational support mechanism; the translational support mechanism is located on the left side of the stabilizing plate (7).
2. The carbon conversion furnace according to claim 1, characterized in that, The translation support mechanism includes a translation port (8), a support rod (9), and a support plate (10). The translation port (8) is located on the left side of the stabilizing plate (7). The support rod (9) is movably connected inside the translation port (8). The right side of the support rod (9) is fixedly connected to the left side of the support (2). The support plate (10) is fixedly connected to the left side of the support rod (9) by bolts.
3. The carbon conversion furnace according to claim 2, characterized in that, The top left side of the stabilizing plate (7) is fixedly connected to a tube (11) that communicates with the translation port (8), and a tube (12) is movably connected inside the tube (11).
4. The carbon conversion furnace according to claim 3, characterized in that, The support rod (9) has a slot (13) on the right side of its top that communicates with the insert (11), and the bottom of the insert (12) is located inside the slot (13).
5. A carbon conversion furnace according to claim 3, characterized in that, The front side of the insertion rod (12) is provided with a sliding groove (14), and the top of the front side of the insertion cylinder (11) is threadedly connected to a sliding bolt (15) located inside the sliding groove (14).
6. The carbon conversion furnace according to claim 1, characterized in that, The front side of the support (2) is movably connected to a card holder (16) located on the left side of the furnace door (3), and the front side of the right side of the card holder (16) is fixedly connected to a rotating handle (17).
7. A carbon conversion furnace according to claim 6, characterized in that, A magnetic plate (18) is inlaid and connected to the left side of the front side of the furnace door (3), and a magnetic plate (19) is inlaid and connected to the right side of the rear side of the card holder (16).
8. A carbon conversion furnace according to claim 6, characterized in that, The support (2) has a threaded groove (20) on its front side, and the threaded groove (20) is threaded with a stud (21) located inside the bracket (16).