Corrosion-resistant dustproof industrial equipment radiator

The heat sink, with its split structure design, solves the problems of inconvenient processing and cleaning in existing technologies, and achieves convenient disassembly and efficient heat dissipation.

CN224340786UActive Publication Date: 2026-06-09DONGGUAN SHIRUI MECHANICAL & ELECTRICAL TECHNOLOGY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
DONGGUAN SHIRUI MECHANICAL & ELECTRICAL TECHNOLOGY CO LTD
Filing Date
2025-05-19
Publication Date
2026-06-09

AI Technical Summary

Technical Problem

The existing radiator structure is not easy to process and shape, and is inconvenient to clean and maintain, which affects the heat dissipation effect.

Method used

It adopts a split structure design, with heat dissipation fins connected by "T" shaped grooves and "I" shaped sliders. Combined with anti-detachment components and docking components, it can be easily disassembled and maintained.

Benefits of technology

It improves heat dissipation efficiency, facilitates cleaning and maintenance, and ensures stable operation of the radiator.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses an anticorrosive dustproof industrial equipment radiator belongs to radiator technical field. This kind of anticorrosive dustproof industrial equipment radiator, including the heat dissipation base, the bottom surface of heat dissipation base is equidistant and is opened with the " T " shape groove, the heat dissipation fin, the heat dissipation fin is engaged in the inside of " T " shape groove and is connected, the heat dissipation fin includes first bent fin board, second bent fin board and third bent fin board, both sides of second bent fin board are equipped with the butt joint subassembly respectively, and second bent fin board is connected with the one side of first bent fin board, third bent fin board respectively through butt joint subassembly, the top of first bent fin board is connected with " the " shape slider, and " the " shape slider slidingly connects in the inside of " T " shape groove, and the heat dissipation base includes the seat board, and the top of seat board is provided with arc recess and arc protruding piece respectively, and arc recess and arc protruding piece are distributed with each other staggered.
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Description

Technical Field

[0001] This utility model relates to the field of radiator technology, specifically a corrosion-resistant and dustproof industrial equipment radiator. Background Technology

[0002] Radiators are typically used to absorb heat generated by equipment or systems and effectively dissipate it into the surrounding environment to ensure the equipment operates within its normal operating temperature range. A search revealed a high-strength, corrosion-resistant aluminum radiator in Chinese patent CN222718767U, comprising a heat dissipation base and several heat dissipation fins. The heat dissipation fins are continuously folded semi-circular structures, arranged parallel and equidistantly along the length of the heat dissipation base. The surfaces of the heat dissipation base and the heat dissipation fins are sequentially provided with a reinforcing layer and a corrosion-resistant layer from the inside out. This design improves the shape of the heat dissipation fins while maintaining a tight arrangement. By designing the heat dissipation fins as continuously folded semi-circular structures, the surface area of ​​the heat dissipation fins in contact with air is increased, and the width of the local channel between two adjacent heat dissipation fins is increased, resulting in a larger airflow through the gap and improved heat dissipation.

[0003] However, in actual use, this solution is difficult to process and shape because the heat dissipation fins and the heat dissipation base are integrally formed and the heat dissipation fins are corrugated. This structure also makes subsequent cleaning and maintenance inconvenient. Utility Model Content

[0004] To address the problems of existing radiators being inconvenient to clean and difficult to process, this utility model provides a corrosion-resistant and dustproof industrial equipment radiator.

[0005] In view of the above problems, the technical solution proposed by this utility model is as follows:

[0006] A corrosion-resistant and dustproof industrial equipment radiator includes a heat dissipation base with T-shaped grooves evenly spaced on the bottom surface of the base; heat dissipation fins that are snapped into the interior of the T-shaped grooves; each heat dissipation fin includes a first curved fin plate, a second curved fin plate, and a third curved fin plate; the second curved fin plate has docking components on both sides, and the second curved fin plate is connected to one side of the first curved fin plate and the third curved fin plate respectively through the docking components; an I-shaped slider is connected to the top of the first curved fin plate, and the I-shaped slider is slidably connected inside the T-shaped groove.

[0007] Furthermore, the heat dissipation base includes a base plate, and the top surface of the base plate is respectively provided with arc-shaped grooves and arc-shaped protrusions, which are distributed alternately.

[0008] The beneficial effect of adopting the above-mentioned further solution is that it increases the contact area between the heat dissipation base and the air, which is conducive to heat dissipation and further improves the heat dissipation efficiency of the entire heat sink. At the same time, this structure also increases the surface area of ​​the heat dissipation base, allowing heat to be transferred into the air more quickly.

[0009] Furthermore, screw holes are provided at the four corners of the seat plate, and two sets of anti-detachment components are provided between the screw holes.

[0010] The advantage of adopting the above-mentioned further solution is that the setting of the screw hole provides positional space for the connection of the bolt in the anti-loosening component.

[0011] Furthermore, each of the two sets of anti-detachment components includes a "U"-shaped frame, with bolts inserted on both sides of the "U"-shaped frame, and one end of the bolts connected to the internal thread of the bolt hole.

[0012] The beneficial effect of adopting the above-mentioned further solution is that the "U"-shaped bracket in the two sets of anti-detachment components can prevent the heat dissipation fins from coming out of the "T"-shaped slot during use, ensuring the normal operation of the heat sink.

[0013] Furthermore, a pad is installed on one side of the "U"-shaped frame, and one side of every two pads contacts both sides of the "I"-shaped slider.

[0014] The beneficial effect of adopting the above-mentioned further solution is that when fixing the "I"-shaped slider to prevent it from falling off, the "U"-shaped frame is prevented from directly contacting the "I"-shaped slider and causing wear. At the same time, the pad can apply pressure to both sides of the "I"-shaped slider more precisely to ensure that the heat dissipation fins will not fall off.

[0015] Furthermore, the docking assembly includes a slot, a protruding corner, and a locking knob. The slot is located at the corner of the first and third curved fin plates, and the protruding corner is located at the corner of the second curved fin plate. The protruding corner engages with the slot, and one end of the locking knob passes through the protruding corner and is connected to the internal thread of the slot.

[0016] The beneficial effect of adopting the above-mentioned further solution is that the connection between the first curved fin plate, the second curved fin plate, and the third curved fin plate is firm and reliable through the locking knob threaded connection.

[0017] Furthermore, the heat dissipation base is provided with connecting pins at its four corners, each connecting pin including a corner plate. The corner plates are welded to the four corners of the heat dissipation base, and the top surface of the corner plates has through holes.

[0018] The advantage of adopting the above-mentioned further solution is that, through the perforations on the corner plate, it can be easily connected to other equipment or mounting brackets, providing more options and convenience for the overall installation of the radiator, and is suitable for different installation scenarios.

[0019] Furthermore, the top surface of the corner plate is flush with the top surface of the arc-shaped protrusion.

[0020] The advantage of adopting the above-mentioned further solution is that when installing the radiator, it can ensure that the heat dissipation base is in flat contact with other equipment or mounting surfaces, avoiding unstable installation or affecting the heat dissipation effect due to unevenness.

[0021] Compared with the prior art, the beneficial effects of this utility model are:

[0022] This corrosion-resistant and dustproof industrial equipment radiator features a modular structure achieved through the interplay of T-shaped grooves and heat dissipation fins. This facilitates disassembly and assembly, simplifying cleaning and maintenance. The disassembled components are also easy to machine. The heat dissipation fins are connected to the T-shaped grooves on the bottom of the heat dissipation base via I-shaped sliders, allowing for convenient installation and removal. Damaged fins can be quickly replaced or maintained. Furthermore, the heat dissipation fins are composed of multiple curved fin plates connected by mating components, allowing for adjustments to the fin structure to meet specific heat dissipation requirements, thus creating a segmented structure. Attached Figure Description

[0023] Figure 1 This utility model provides an assembly perspective view of a corrosion-resistant and dustproof industrial equipment radiator.

[0024] Figure 2 A schematic diagram of a heat dissipation base structure for a corrosion-resistant and dustproof industrial equipment radiator provided by this utility model;

[0025] Figure 3 A schematic diagram of the unfolded heat dissipation fins of a corrosion-resistant and dustproof industrial equipment radiator provided by this utility model;

[0026] Figure 4 An enlarged schematic diagram of the docking assembly of a corrosion-resistant and dustproof industrial equipment radiator provided by this utility model;

[0027] Figure 5 A schematic diagram of an anti-detachment component for a corrosion-resistant and dustproof industrial equipment radiator provided by this utility model.

[0028] In the diagram: 100, heat dissipation base; 1001, base plate; 1002, arc-shaped groove; 1003, arc-shaped protrusion; 1004, screw hole; 200, heat dissipation fins; 2001, "I"-shaped slider; 2002, first curved fin plate; 2003, second curved fin plate; 2004, third curved fin plate; 300, anti-detachment component; 3001, "U"-shaped frame; 3002, bolt; 3003, pad; 400, connecting pin; 4001, corner plate; 4002, through hole; 500, "T"-shaped groove; 600, docking component; 6001, slot; 6002, protruding corner; 6003, locking knob. Detailed Implementation

[0029] 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.

[0030] Please see Figures 1-5 This utility model provides a technical solution: a corrosion-resistant and dustproof industrial equipment radiator, including a heat dissipation base 100, with T-shaped grooves 500 evenly spaced on the bottom surface of the heat dissipation base 100; heat dissipation fins 200, which are snapped into the interior of the T-shaped grooves 500. Each heat dissipation fin 200 includes a first curved fin plate 2002, a second curved fin plate 2003, and a third curved fin plate 2004. The second curved fin plate 2003 has docking components 600 on both sides. 3. The heat dissipation fins are connected to one side of the first curved fin plate 2002 and the third curved fin plate 2004 respectively via the docking assembly 600. The top of the first curved fin plate 2002 is connected to an "I"-shaped slider 2001, which is slidably connected inside the "T"-shaped groove 500. The heat dissipation fins 200 are engaged with the "T"-shaped groove 500 on the bottom surface of the heat dissipation base 100 via the "I"-shaped slider 2001, making installation and disassembly convenient. When the heat dissipation fins are damaged or need cleaning, they can be quickly replaced or maintained. At the same time, the heat dissipation fins 200 are made up of multiple curved fin plates connected by the docking assembly 600, which facilitates the adjustment of the fin structure according to the actual heat dissipation requirements, thus forming a segmented structure.

[0031] 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.

[0032] As an embodiment of this utility model, the heat dissipation base 100 further includes a base plate 1001. The top surface of the base plate 1001 is respectively provided with arc-shaped grooves 1002 and arc-shaped protrusions 1003. The arc-shaped grooves 1002 and arc-shaped protrusions 1003 are distributed alternately, increasing the contact area between the heat dissipation base 100 and the air, which is conducive to heat dissipation and further improves the heat dissipation efficiency of the entire heat sink. At the same time, this structure also increases the surface area of ​​the heat dissipation base, allowing heat to be transferred to the air more quickly. Screw holes 1004 are respectively opened at the four corners of the base plate 1001. Two sets of anti-detachment components 300 are provided between the screw holes 1004. The screw holes 1004 provide positional space for the connection of the bolts 3002 in the anti-detachment components 300.

[0033] As an embodiment of this utility model, further, the two sets of anti-detachment components 300 each include a "U"-shaped frame 3001, with bolts 3002 inserted on both sides of the "U"-shaped frame 3001. One end of the bolts 3002 is connected to the internal thread of the screw hole 1004. The "U"-shaped frame 3001 in the two sets of anti-detachment components 300 can prevent the heat dissipation fins 200 from coming out of the "T"-shaped groove 500 during use, ensuring the normal operation of the heat sink. A pad 3003 is installed on one side of the "U"-shaped frame 3001. One side of every two pads 3003 contacts both sides of the "I"-shaped slider 2001. When fixing the "I"-shaped slider 2001 to prevent detachment, the "U"-shaped frame 3001 is prevented from directly contacting the "I"-shaped slider 2001 and causing wear. At the same time, the pads 3003 can apply pressure to both sides of the "I"-shaped slider 2001 more precisely, ensuring that the heat dissipation fins 200 will not come out.

[0034] As an embodiment of this utility model, the docking assembly 600 further includes a slot 6001, a protruding corner 6002, and a locking knob 6003. The slot 6001 is disposed at the corner of the first curved fin plate 2002 and the third curved fin plate 2004, and the protruding corner 6002 is disposed at the corner of the second curved fin plate 2003. The protruding corner 6002 and the slot 6001 engage with each other. One end of the locking knob 6003 passes through the protruding corner 6002 and is threadedly connected to the inside of the slot 6001. Through the threaded connection of the locking knob 6003, the connection between the first curved fin plate 2002, the second curved fin plate 2003, and the third curved fin plate 2004 is firm and reliable.

[0035] As an embodiment of this utility model, the heat dissipation base 100 is further provided with connection pins 400 at its four corners. Each connection pin 400 includes a corner plate 4001. The corner plates 4001 are welded to the four corners of the heat dissipation base 100. A through hole 4002 is provided on the top surface of the corner plate 4001. Through the through hole 4002 on the corner plate 4001, it can be easily connected to other devices or mounting brackets, providing more options and convenience for the overall installation of the heat dissipation unit, and is suitable for different installation scenarios.

[0036] As an embodiment of this utility model, the top surface of the corner plate 4001 is flush with the top surface of the arc-shaped protrusion 1003. When installing the heat sink, it can ensure that the heat sink base 100 is in flat contact with other equipment or mounting surfaces, and avoid unstable installation or affecting the heat dissipation effect due to unevenness.

[0037] Specifically, the working principle of this corrosion-resistant and dustproof industrial equipment radiator is as follows: During use, the heat dissipation base 100 is connected to the industrial equipment through the four corner screw holes 1004 of the base plate 1001. The interlaced arc-shaped grooves 1002 and arc-shaped protrusions 1003 on the top surface of the base plate 1001 increase the contact area with air, accelerating heat dissipation. The corner plates 4001 welded at the four corners have through holes 4002 for connecting to other equipment or supports, and the top surface of the corner plates 4001 is flush with the top surface of the arc-shaped protrusions 1003, ensuring flatness and stability during installation. The "I"-shaped slider 2001 at the top of the first curved fin plate 2002 of the heat dissipation fins 200 engages with the "T"-shaped groove 500 on the bottom surface of the heat dissipation base 100, enabling convenient installation and disassembly for easy maintenance and replacement. The second curved fin plate 2003 is connected to the first and third curved fin plates respectively via the two side docking components 600. After the slot 6001 and the convex corner 6002 are engaged, they are connected by a locking knob 6003 threadedly to ensure that the fins are firmly connected. During use, the bolts 3002 on both sides of the "U"-shaped frame 3001 of the two sets of anti-detachment components 300 are screwed into the screw holes 1004. The pad 3003 on one side of the "U"-shaped frame 3001 precisely abuts against both sides of the "I"-shaped slider 2001 to prevent the heat dissipation fins 200 from coming out of the "T"-shaped groove 500, ensuring stable operation of the heat sink and efficient heat dissipation for industrial equipment.

Claims

1. A corrosion-resistant and dustproof industrial equipment radiator, characterized in that, include: A heat dissipation base (100) has T-shaped grooves (500) evenly spaced on its bottom surface; heat dissipation fins (200) are engaged with the interior of the T-shaped grooves (500), and the heat dissipation fins (200) include a first curved fin plate (2002), a second curved fin plate (2003), and a third curved fin plate (2004). The second curved fin plate (2003) has docking components (600) on both sides, and the second curved fin plate (2003) is connected to one side of the first curved fin plate (2002) and the third curved fin plate (2004) respectively through the docking components (600). The top of the first curved fin plate (2002) is connected to an I-shaped slider (2001), and the I-shaped slider (2001) is slidably connected to the interior of the T-shaped grooves (500).

2. The corrosion-resistant and dustproof industrial equipment radiator according to claim 1, characterized in that, The heat dissipation base (100) includes a base plate (1001), and the top surface of the base plate (1001) is provided with arc-shaped grooves (1002) and arc-shaped protrusions (1003), which are distributed alternately.

3. The corrosion-resistant and dustproof industrial equipment radiator according to claim 2, characterized in that, The four corners of the seat plate (1001) are provided with screw holes (1004), and two sets of anti-detachment components (300) are provided between the screw holes (1004).

4. A corrosion-resistant and dustproof industrial equipment radiator according to claim 3, characterized in that, The two sets of anti-detachment components (300) each include a "U" shaped frame (3001), and bolts (3002) are inserted on both sides of the "U" shaped frame (3001). One end of the bolt (3002) is connected to the internal thread of the screw hole (1004).

5. A corrosion-resistant and dustproof industrial equipment radiator according to claim 4, characterized in that, A pad (3003) is installed on one side of the "U"-shaped frame (3001), and one side of every two pads (3003) contacts the two sides of the "I"-shaped slider (2001).

6. A corrosion-resistant and dustproof industrial equipment radiator according to claim 1, characterized in that, The docking assembly (600) includes a slot (6001), a protruding corner (6002), and a locking knob (6003). The slot (6001) is located at the corner of the first curved fin plate (2002) and the third curved fin plate (2004). The protruding corner (6002) is located at the corner of the second curved fin plate (2003). The protruding corner (6002) engages with the slot (6001). One end of the locking knob (6003) passes through the protruding corner (6002) and is threadedly connected to the inside of the slot (6001).

7. A corrosion-resistant and dustproof industrial equipment radiator according to claim 2, characterized in that, The heat dissipation base (100) is provided with connection pins (400) at its four corners. Each connection pin (400) includes a corner plate (4001). The corner plates (4001) are welded to the four corners of the heat dissipation base (100). A through hole (4002) is provided on the top surface of the corner plate (4001).

8. A corrosion-resistant and dustproof industrial equipment radiator according to claim 7, characterized in that, The top surface of the corner plate (4001) is flush with the top surface of the arc-shaped protrusion (1003).