Energy-saving heat preservation furnace for building aluminum powder production and processing

By introducing a flow guiding mechanism and a lubrication mechanism into the energy-saving heat preservation furnace, the problem of position change during the pouring of molten aluminum is solved, achieving stable flow and convenient transfer of molten aluminum, and improving operational efficiency.

CN224398290UActive Publication Date: 2026-06-23BINZHOU XILONG BUILDING MATERIALS CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
BINZHOU XILONG BUILDING MATERIALS CO LTD
Filing Date
2025-06-30
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

When pouring molten aluminum from an existing energy-saving heat preservation furnace, the limited length of the outlet causes the molten aluminum to flow out at a different location, making it inconvenient to collect and transport.

Method used

An energy-saving heat-insulating furnace for the production and processing of building aluminum powder was designed, which includes a flow guiding mechanism and a lubrication mechanism. The flow guiding channel and the fixed shaft are connected to achieve stable flow of aluminum liquid, and the connection between the lubricating oil tank and the liquid delivery channel provides lubrication treatment to ensure the stability of the aluminum liquid position during the pouring process.

Benefits of technology

This achieves positional stability of molten aluminum during pouring, facilitating its collection and transfer, and improving operational convenience and efficiency.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model relates to building aluminium powder production and processing technical field, concretely is a kind of energy-saving heat preservation furnace for building aluminium powder production and processing, it includes: frame, including support frame, the surface of support frame is provided with tiltable heat preservation furnace;Flow guide mechanism, including first fixed shaft, the first fixed shaft fixedly connected in the surface of tiltable heat preservation furnace.The utility model can make first flow guide groove change position and inclination with the rotation of tiltable heat preservation furnace by the connection of tiltable heat preservation furnace and first fixed shaft, can make second flow guide groove change inclination following first flow guide groove movement, limit block moves at limit slot, so that second flow guide groove can be telescopic on the surface of first flow guide groove, again by the connection of support frame and second fixed shaft, so that second flow guide groove changes inclination, aluminium water is always unchanged at second flow guide groove outlet end position, it is convenient to collect and transport to aluminium water, reach the effect that aluminium water can be flow guided.
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Description

Technical Field

[0001] This utility model relates to the field of building aluminum powder production and processing technology, specifically to an energy-saving heat-insulating furnace for building aluminum powder production and processing. Background Technology

[0002] The production and processing of architectural aluminum powder refers to the process of turning aluminum into powdered material through specific processes. It is mainly used in the field of building materials. The production and processing of architectural aluminum powder includes a variety of methods, among which the most common are ball milling and atomization.

[0003] Energy-saving heat preservation furnaces are indispensable equipment in aluminum processing. Their functions include improving processing efficiency, improving product quality, and saving costs. They use resistance heating or gas heating to heat aluminum products to a certain temperature, and then use heat preservation measures to maintain the temperature until the desired processing effect is achieved. However, when using existing energy-saving heat preservation furnaces, the limited length of the outlet when pouring molten aluminum causes the position of the molten aluminum to change during the rotation and pouring process, making it inconvenient for collection and transportation. Utility Model Content

[0004] The purpose of this utility model is to provide an energy-saving heat-insulating furnace for the production and processing of aluminum powder for building construction, so as to solve the problem mentioned in the background art that when the energy-saving heat-insulating furnace is used, the limited length of the outlet when pouring molten aluminum causes the position of the molten aluminum to change during the rotation and pouring process, making it inconvenient for collection and transportation.

[0005] To achieve the above objectives, this utility model provides the following technical solution: an energy-saving heat-insulating furnace for the production and processing of aluminum powder for construction, comprising:

[0006] The frame includes a support frame, the surface of which is provided with a tiltable heat preservation furnace;

[0007] The flow guiding mechanism includes a first fixed shaft, which is fixedly connected to the surface of the tilting heat preservation furnace. A first flow guiding groove is rotatably connected to the surface of the first fixed shaft. A limit block is fixedly connected to the surface of the first flow guiding groove. A second fixed shaft is fixedly connected to the surface of the support frame. A second flow guiding groove is rotatably connected to the surface of the second fixed shaft. A limit groove is formed on the surface of the second flow guiding groove.

[0008] Preferably, the first fixed shafts are symmetrically distributed in two sets on the surface of the tilting heat preservation furnace, and the first guide channel is rotatably connected to the surface of the tilting heat preservation furnace through the first fixed shafts.

[0009] Preferably, the second fixed shafts are symmetrically distributed in two sets on the surface of the support frame, and the second guide groove is rotatably connected to the surface of the support frame through the second fixed shafts.

[0010] Preferably, the limiting blocks are symmetrically distributed in two groups on the surface of the first guide groove, the limiting grooves are symmetrically opened in two groups on the surface of the second guide groove, and the limiting blocks are movably connected to the surface of the limiting grooves.

[0011] Preferably, the second guide channel is movably connected to the surface of the first guide channel via a limiting groove, the first guide channel is rotatably connected to the surface of the support frame via a second fixed shaft, and the second guide channel is rotatably connected to the surface of the tilting heat preservation furnace via a first fixed shaft.

[0012] Preferably, the lubrication mechanism includes a lubricating oil tank, which is fixedly connected to the surface of the support frame. The lubricating oil tank has an infusion channel inside, and a flow control block is movably connected inside the lubricating oil tank. A connecting threaded rod is fixedly connected to the surface of the flow control block, and an adjustment knob is fixedly connected to the end of the connecting threaded rod away from the flow control block.

[0013] Preferably, the threaded connecting rod is threaded onto the surface of the lubricating oil tank, and the threaded connecting rod is rotatably connected to the surface of the lubricating oil tank via an adjusting knob.

[0014] Preferably, the lubricating oil tank is connected to the internal passage of the support frame via the infusion channel, and the flow control block is internally movablely connected to the infusion channel via a connecting threaded rod.

[0015] Compared with the prior art, the beneficial effects of this utility model are:

[0016] 1. By connecting the tilting holding furnace and the first fixed shaft, and the first fixed shaft and the first guide channel, the position and inclination of the first guide channel can be changed as the tilting holding furnace rotates. Then, by connecting the limiting block and the second guide channel, and the limiting block and the limiting channel, the inclination of the second guide channel can be changed as the first guide channel moves. The limiting block moves at the limiting channel, allowing the second guide channel to extend and retract on the surface of the first guide channel. Furthermore, by connecting the support frame and the second fixed shaft, and the second fixed shaft and the second guide channel, the position of the molten aluminum at the outlet end of the second guide channel remains unchanged when the inclination of the second guide channel changes, facilitating the collection and transfer of molten aluminum and achieving the effect of guiding the molten aluminum.

[0017] 2. By connecting the support frame and the lubricating oil tank, and connecting the lubricating oil tank and the infusion channel, the lubricating oil inside the lubricating oil tank can flow along the infusion channel to the connection between the support frame and the tilting insulation furnace for lubrication. Then, by connecting the adjusting knob and the connecting threaded rod, and connecting the connecting threaded rod and the flow control block, the adjusting knob can be rotated to drive the connecting threaded rod and the flow control block to rotate and move, thereby controlling the flow of lubricating oil and achieving the effect of lubricating the connection between the support frame and the tilting insulation furnace. Attached Figure Description

[0018] Figure 1 This is a three-dimensional front view of the structure of this utility model;

[0019] Figure 2 This is a side-view perspective view of the structure of this utility model;

[0020] Figure 3 This is a partial three-dimensional schematic diagram of the connection structure between the tilting heat preservation furnace and the second guide channel of this utility model.

[0021] Figure 4 This is a three-dimensional partial cross-sectional view of the connection structure between the first and second guide channels of this utility model;

[0022] Figure 5 This is a partial three-dimensional sectional view of the connection structure between the tilting heat preservation furnace and the lubricating oil tank of this utility model.

[0023] In the diagram: 1. Support frame; 11. Tilting insulation furnace; 2. First fixed shaft; 21. First guide channel; 22. Limiting block; 23. Second fixed shaft; 24. Second guide channel; 25. Limiting channel; 3. Lubricating oil tank; 31. Infusion channel; 32. Flow control block; 33. Connecting threaded rod; 34. Adjusting knob. Detailed Implementation

[0024] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0025] Please see Figure 1-5 One embodiment provided by this utility model:

[0026] An energy-saving heat-insulating furnace for the production and processing of aluminum powder for building applications, comprising:

[0027] The frame includes a support frame 1, and a tilting heat preservation furnace 11 is provided on the surface of the support frame 1. Both the support frame 1 and the tilting heat preservation furnace 11 are existing products and are not considered as technical protection points of this application. They will not be described in detail here.

[0028] The flow guiding mechanism includes a first fixed shaft 2, which is fixedly connected to the surface of the tilting holding furnace 11 and is used to connect to a first flow guiding groove 21. The surface of the first fixed shaft 2 is rotatably connected to the first flow guiding groove 21 for guiding the molten aluminum. A limiting block 22 is fixedly connected to the surface of the first flow guiding groove 21 for connecting to a second flow guiding groove 24. A second fixed shaft 23 is fixedly connected to the surface of the support frame 1 for connecting to the second flow guiding groove 24. The surface of the second fixed shaft 23 is rotatably connected to the second flow guiding groove 24 for guiding the molten aluminum. A limiting groove 25 is formed on the surface of the second flow guiding groove 24 for connecting to the limiting block 22.

[0029] Furthermore, the first fixed shaft 2 is symmetrically distributed in two sets on the surface of the tilting heat preservation furnace 11. The first guide channel 21 is rotatably connected to the surface of the tilting heat preservation furnace 11 through the first fixed shaft 2. When the tilting heat preservation furnace 11 rotates, the position of the first fixed shaft 2 will change, and the inclination of the first guide channel 21 will change accordingly. The first guide channel 21 rotates on the surface of the first fixed shaft 2.

[0030] Furthermore, the second fixed shaft 23 is symmetrically distributed in two sets on the surface of the support frame 1. The second guide channel 24 is rotatably connected to the surface of the support frame 1 through the second fixed shaft 23. The change of the inclination of the first guide channel 21 causes the change of the inclination of the second guide channel 24, so that the second guide channel 24 rotates on the surface of the second fixed shaft 23.

[0031] Furthermore, the limiting blocks 22 are symmetrically distributed in two sets on the surface of the first guide groove 21, and the limiting grooves 25 are symmetrically opened in two sets on the surface of the second guide groove 24. The limiting blocks 22 are movably connected to the surface of the limiting grooves 25. When the position of the first fixed shaft 2 changes, the position of the second fixed shaft 23 remains unchanged, causing the second guide groove 24 to extend on the surface of the first guide groove 21, thereby allowing the limiting blocks 22 to move at the limiting grooves 25.

[0032] Furthermore, the second guide channel 24 is movably connected to the surface of the first guide channel 21 via the limiting groove 25. The first guide channel 21 is rotatably connected to the surface of the support frame 1 via the second fixed shaft 23. The second guide channel 24 is rotatably connected to the surface of the tilting holding furnace 11 via the first fixed shaft 2. The second guide channel 24 is pulled out on the surface of the first guide channel 21 as the position and inclination of the first guide channel 21 change, thereby ensuring that the molten aluminum always flows out from the same position in the second guide channel 24, which facilitates collection and transfer.

[0033] Furthermore, the lubrication mechanism includes a lubricating oil tank 3, which is fixedly connected to the surface of the support frame 1 for storing lubricating oil. The lubricating oil tank 3 has an internal delivery channel 31 for the lubricating oil to flow to the surface of the rotating shaft of the tilting heat preservation furnace 11. A flow control block 32 is movably connected inside the lubricating oil tank 3 for controlling the flow of lubricating oil. A connecting threaded rod 33 is fixedly connected to the surface of the flow control block 32 for connecting the flow control block 32 and the adjusting knob 34. The end of the connecting threaded rod 33 away from the flow control block 32 is fixedly connected to the adjusting knob 34 for driving the flow control block 32 to rotate and move.

[0034] Furthermore, the threaded rod 33 is threaded onto the surface of the lubricating oil tank 3, which prevents the flow control block 32 and the adjusting knob 34 from moving without external force. The threaded rod 33 is rotatably connected to the surface of the lubricating oil tank 3 through the adjusting knob 34, and rotating the adjusting knob 34 can drive the threaded rod 33 to rotate and move.

[0035] Furthermore, the lubricating oil tank 3 is connected to the internal passage of the support frame 1 through the infusion channel 31, and the flow control block 32 is connected to the internal movement of the infusion channel 31 through the connecting threaded rod 33. The rotation of the connecting threaded rod 33 drives the flow control block 32 to rotate, thereby causing the flow control block 32 to leave the inside of the infusion channel 31, so that the lubricating oil can flow along the infusion channel 31 to the connection between the support frame 1 and the tilting heat preservation furnace 11.

[0036] Working principle: When the tilting furnace 11 is used, its rotation causes the position of the first fixed shaft 2 to change, thus changing the inclination of the first guide channel 21. The first guide channel 21 rotates on the surface of the first fixed shaft 2, and this change in inclination causes the inclination of the second guide channel 24 to change as well. This causes the second guide channel 24 to rotate on the surface of the second fixed shaft 23. The position of the first fixed shaft 2 changes, while the position of the second fixed shaft 23 remains unchanged, causing the second guide channel 24 to extend on the surface of the first guide channel 21, thereby extending the position of the limiting block 22. The second guide groove 24 moves at the limiting groove 25 and is pulled on the surface of the first guide groove 21 as the position and inclination of the first guide groove 21 change, thereby ensuring that the molten aluminum always flows out from the same position in the second guide groove 24, which is convenient for collection and transfer. When it is necessary to lubricate the connection between the support frame 1 and the tilting holding furnace 11, rotating the adjustment knob 34 can drive the connecting threaded rod 33 and the flow control block 32 to rotate and move, thereby causing the flow control block 32 to leave the inside of the liquid delivery channel 31, so that the lubricating oil can flow along the liquid delivery channel 31 to the connection between the support frame 1 and the tilting holding furnace 11.

[0037] It will be apparent to those skilled in the art that this invention is not limited to the details of the exemplary embodiments described above, and that it can be implemented in other specific forms without departing from the spirit or essential characteristics of this invention. Therefore, the embodiments should be considered illustrative and non-limiting in all respects, and the scope of this invention is defined by the appended claims rather than the foregoing description. Thus, it is intended that all variations falling within the meaning and scope of equivalents of the claims be included within this invention. No reference numerals in the claims should be construed as limiting the scope of the claims.

Claims

1. An energy-saving heat-insulating furnace for the production and processing of aluminum powder for construction, characterized in that, include: The frame includes a support frame (1), and a tiltable heat preservation furnace (11) is provided on the surface of the support frame (1). The flow guiding mechanism includes a first fixed shaft (2), which is fixedly connected to the surface of the tilting heat preservation furnace (11). A first flow guiding groove (21) is rotatably connected to the surface of the first fixed shaft (2), and a limit block (22) is fixedly connected to the surface of the first flow guiding groove (21). A second fixed shaft (23) is fixedly connected to the surface of the support frame (1), and a second flow guiding groove (24) is rotatably connected to the surface of the second fixed shaft (23). A limit groove (25) is formed on the surface of the second flow guiding groove (24).

2. The energy-saving heat-insulating furnace for the production and processing of aluminum powder for building construction according to claim 1, characterized in that: The first fixed shaft (2) is symmetrically distributed in two groups on the surface of the tilting heat preservation furnace (11), and the first guide groove (21) is rotatably connected to the surface of the tilting heat preservation furnace (11) through the first fixed shaft (2).

3. The energy-saving heat-insulating furnace for the production and processing of aluminum powder for building construction according to claim 1, characterized in that: The second fixed shaft (23) is symmetrically distributed in two groups on the surface of the support frame (1), and the second guide groove (24) is rotatably connected to the surface of the support frame (1) through the second fixed shaft (23).

4. The energy-saving heat-insulating furnace for the production and processing of aluminum powder for building construction according to claim 1, characterized in that: The limiting blocks (22) are symmetrically distributed in two groups on the surface of the first guide groove (21), and the limiting grooves (25) are symmetrically opened in two groups on the surface of the second guide groove (24). The limiting blocks (22) are movably connected to the surface of the limiting grooves (25).

5. The energy-saving and heat-insulating furnace for the production and processing of aluminum powder for building construction according to claim 1, characterized in that: The second guide channel (24) is movably connected to the surface of the first guide channel (21) through the limiting groove (25), the first guide channel (21) is rotatably connected to the surface of the support frame (1) through the second fixed shaft (23), and the second guide channel (24) is rotatably connected to the surface of the tilting heat preservation furnace (11) through the first fixed shaft (2).

6. The energy-saving heat-insulating furnace for the production and processing of aluminum powder for building construction according to claim 1, characterized in that: The lubrication mechanism includes a lubricating oil tank (3), which is fixedly connected to the surface of the support frame (1). The lubricating oil tank (3) has an infusion channel (31) inside. A flow control block (32) is movably connected inside the lubricating oil tank (3). A connecting threaded rod (33) is fixedly connected to the surface of the flow control block (32). An adjustment knob (34) is fixedly connected to the end of the connecting threaded rod (33) away from the flow control block (32).

7. The energy-saving heat-insulating furnace for the production and processing of aluminum powder for building construction according to claim 6, characterized in that: The connecting threaded rod (33) is threaded onto the surface of the lubricating oil tank (3), and the connecting threaded rod (33) is rotatably connected to the surface of the lubricating oil tank (3) through the adjusting knob (34).

8. The energy-saving heat-insulating furnace for the production and processing of aluminum powder for building construction according to claim 6, characterized in that: The lubricating oil tank (3) is connected to the internal passage of the support frame (1) through the infusion channel (31), and the flow control block (32) is internally connected to the infusion channel (31) through the connecting threaded rod (33).