A detachable modular condenser device
The modular design of the condenser unit enables the independent disassembly of the heat dissipation fins and cooling heat exchange tubes, solving the waste and high cost problems caused by the traditional whole-unit replacement of the condenser, reducing maintenance costs and improving maintenance efficiency.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Filing Date
- 2025-06-19
- Publication Date
- 2026-07-07
AI Technical Summary
Traditional condensers have an integrated structure of fins and cooling heat exchange tubes, which means that even if the undamaged parts are damaged, the entire unit needs to be replaced, resulting in waste and high maintenance costs.
It adopts a detachable modular design, which allows for the independent disassembly of the heat dissipation fins and cooling heat exchange tubes through components such as cover plates, frames, pillars and locking tongues. The combination structure of push springs and locking tongues enables quick locking and unlocking, realizing modular disassembly.
This effectively avoids the waste of undamaged parts, reduces the replacement and maintenance costs of the condenser, and improves maintenance efficiency.
Smart Images

Figure CN224470493U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of condensers, and more specifically, it relates to a detachable modular condenser device. Background Technology
[0002] A condenser is a heat exchange component in air conditioning and dehumidifier refrigeration systems. Its main function is to cool gas or vapor and convert it into liquid, then rapidly transfer the heat to the surrounding air to complete the heat release process. Currently, condensers typically use a finned structure on the outside of the heat exchange tubes to dissipate heat from the tubes using the principle of air convection. However, traditional condenser fins and heat exchange tubes are usually rigidly connected as a single unit. Therefore, whether any set of fins in the multi-fin structure is bent and damaged, or the heat exchange tube body is broken and leaking, the entire condenser unit needs to be replaced to ensure normal cooling and heat exchange operation. This method of replacing the entire condenser not only wastes undamaged components but also significantly increases the cost of replacing and maintaining damaged condensers. Utility Model Content
[0003] To address the aforementioned technical problems, this utility model provides a detachable modular condenser device, which solves the problem of waste and high replacement and maintenance costs caused by the integrated structure of fins and cooling heat exchange in traditional condensers, which requires replacing undamaged parts along with damaged parts.
[0004] This utility model provides a detachable modular condenser device, including a heat dissipation fin plate; the heat dissipation fin plate has a semi-circular opening groove that runs from left to right, and a cooling heat exchange tube is embedded in the semi-circular opening groove; it also includes a frame, a support column, and a rotating rod; the top and bottom of the support column are connected to a cover plate by bolts; the front side of the frame is welded with an insert block; the frame is a rectangular frame structure; the upper and lower sides of the rectangular frame structure are provided with grooves; the heat dissipation fin plate is inserted into the grooves of the frame; the front side of the frame has a semi-circular groove; the cooling heat exchange tube is inserted into the semi-circular groove of the frame; the top of the rotating rod is welded with a pull handle; the bottom of the rotating rod is rotatably connected with a locking tongue; the upper side of the locking tongue is welded with a push spring; and the outer side of the rotating rod near the top is welded with a locking block.
[0005] In at least some embodiments, the number of cover plates is two sets, and the cover plates are symmetrically distributed on the upper and lower sides. Each set of cover plates has fifty-three sets of rectangular opening grooves on the rear side. The top and bottom parts of the heat dissipation fins are respectively inserted into the rectangular opening grooves of the cover plates. The upper side of the cover plate has a circular groove near the left and right ends. The center of the bottom of the circular groove of the cover plate has a through hole that runs vertically through the bottom. The inner side of each through hole has a through opening groove that runs vertically through the bottom.
[0006] In at least some embodiments, the number of the support pillars is two sets, and each set of support pillars has a rectangular through groove running from front to back on the front side. The upper wall of the rectangular through groove has a square through groove. A locking tongue is inserted into the square through groove of the support pillar. The rear side of the support pillar has a semi-circular opening groove, and a cooling heat exchange pipe is embedded in the semi-circular opening groove of the support pillar.
[0007] In at least some embodiments, the number of the inserts is four groups, with each pair of inserts symmetrically distributed vertically. Each group of inserts has a through-hole groove, and a locking tongue is embedded in the through-hole groove of the insert.
[0008] In at least some embodiments, the number of locking tongues is four, and each group of locking tongues has a beveled structure on the rear side near the bottom.
[0009] In at least some embodiments, the number of push springs is four sets, with a locking tongue welded to one end of each push spring and a cover plate welded to the other end.
[0010] Compared with the prior art, the present invention has the following beneficial effects:
[0011] 1. In this utility model, on the one hand, the vertical independent insertion structure of the heat dissipation fins is achieved through the opening groove of the cover plate and the opening groove inside the frame, allowing the fifty-three sets of heat dissipation fins to be disassembled and separated individually. On the other hand, the elastic force of the push spring itself is used to squeeze and push the locking tongue in the opening groove of the insertion block to form an insertion locking structure. This allows the semi-circular opening groove of the support column to cooperate with the semi-circular opening groove of the frame to clamp and fix the cooling heat exchange tube and the reverse side in opposite directions. This facilitates the independent separation and removal of the cooling heat exchange tube from the fifty-three sets of heat dissipation fins after damage. This abandons the integrated structure of the cooling heat exchange tube and heat dissipation fins of the traditional condenser, realizes the modular disassembly and replacement of the condenser, effectively avoids the waste of materials for undamaged cooling heat exchange tubes and undamaged heat dissipation fins, and reduces the replacement and maintenance cost of the condenser. Attached Figure Description
[0012] Figure 1 This is a schematic diagram of the structure of this utility model.
[0013] Figure 2 This is a front view structural diagram of this utility model.
[0014] Figure 3 This is a schematic diagram of the structure of this utility model from a bottom view.
[0015] Figure 4 This is an exploded structural diagram of the present invention.
[0016] Figure 5 This is a schematic diagram of the locked state cross-section structure of this utility model.
[0017] Figure 6 This is the utility model Figure 5 Enlarged structural diagram of part A in the middle.
[0018] Figure 7 This is a cross-sectional view of the unlocked state of this utility model.
[0019] Figure 8 This is the utility model Figure 7 Enlarged structural diagram of part B in the middle.
[0020] Figure 9 This is the utility model Figure 4 Enlarged structural diagram of part C in the middle.
[0021] Figure 10 This is the utility model Figure 4 Enlarged structural diagram of part D in the middle.
[0022] Reference numerals: 1. Frame; 2. Cover plate; 3. Cooling heat exchange tube; 4. Pull handle; 5. Insert block; 6. Heat dissipation fin plate; 7. Support column; 8. Locking tongue; 9. Push spring; 10. Rotating rod; 11. Locking block. Detailed Implementation
[0023] The embodiments of this utility model will be described in further detail below with reference to the accompanying drawings and examples. The following examples are for illustrative purposes only and should not be construed as limiting the scope of this utility model.
[0024] like Figures 1-10 As shown, this utility model provides a detachable modular condenser device, including a heat dissipation fin plate 6; the heat dissipation fin plate 6 has a semi-circular opening groove that runs through it from left to right, and a cooling heat exchange tube 3 is embedded in the semi-circular opening groove; it also includes a frame 1, a support column 7 and a rotating rod 10; the top and bottom ends of the support column 7 are connected to a cover plate 2 by bolts; the front side of the frame 1 is welded with an insert block 5; the frame 1 is a rectangular frame structure; the upper and lower sides of the rectangular frame structure of the frame 1 are provided with grooves; the heat dissipation fin plate 6 is inserted into the grooves of the frame 1; the front side of the frame 1 has a semi-circular groove; the cooling heat exchange tube 3 is inserted through the semi-circular groove of the frame 1; the top end of the rotating rod 10 is welded with a pull handle 4; the bottom end of the rotating rod 10 is rotatably connected with a locking tongue 8; the upper side of the locking tongue 8 is welded with a push spring 9; and the outer side of the rotating rod 10 near the top end is welded with a locking block 11.
[0025] In this embodiment, there are two sets of cover plates 2, symmetrically distributed vertically. Each set of cover plates 2 has fifty-three sets of rectangular opening grooves on its rear side. The top and bottom parts of the heat dissipation fins 6 are respectively inserted into the rectangular opening grooves of the cover plate 2, so that the rectangular opening grooves of the two sets of cover plates 2 continue to provide independent vertical support for the fifty-three sets of heat dissipation fins 6. When the frame 1 is separated from the support column 7, the damaged heat dissipation fins 6 among the fifty-three sets of heat dissipation fins 6 can be individually disassembled and separated from the rectangular opening grooves of the cover plate 2, while the undamaged heat dissipation fins 6 are retained, avoiding the material waste caused by replacing the entire heat dissipation fins 6. The upper side of plate 2 is provided with a circular groove near the left and right ends. The center of the bottom of the circular groove of the cover plate 2 is provided with a through hole that runs vertically through the groove. The inner side of each through hole is provided with a groove that runs vertically through the groove. When the bottom of the locking block 11 connected to the rotating rod 10 by the pull handle 4 is higher than the bottom of the circular groove of the cover plate 2 and rotates away from the groove of the circular groove of the cover plate 2, the lower side of the locking block 11 fits against the bottom of the circular groove of the cover plate 2 to support and limit the locking tongue 8, so as to prevent the push spring 9 from pushing the locking tongue 8 into the groove of the insert 5, so that the locking tongue 8 is always away from the groove of the insert 5, and the frame 1 and the support column 7 can be disassembled and separated.
[0026] In this embodiment, there are two sets of support pillars 7. Each set of support pillars 7 has a rectangular through groove running from front to back on its front side. The upper wall of the rectangular through groove has a square through groove. A locking tongue 8 is inserted into the square through groove of the support pillar 7, so that the outer side of the locking tongue 8 fits against the wall of the square through groove. The square through groove of the support pillar 7 supports the locking tongue 8 to slide vertically in an up-down direction, ensuring that the locking tongue 8 is stably and accurately inserted into the opening groove of the insert block 5 for locking. The rear side of the support pillar 7 has a semi-circular opening groove, and a cooling heat exchange pipe 3 is embedded in the semi-circular opening groove of the support pillar 7.
[0027] In this embodiment, there are four sets of insert blocks 5, with each pair of insert blocks 5 symmetrically distributed vertically. Each set of insert blocks 5 has a through-hole groove on both sides. A locking tongue 8 is embedded in the through-hole groove of the insert block 5. When the frame 1 and the support column 7 are in front and back contact, the front side of the locking tongue 8 is attached to the front side groove wall of the through-hole groove of the insert block 5. The locking tongue 8 limits and locks the insert block 5 to move backward, so that the frame 1 and the support column 7 are stably closed front and back.
[0028] In this embodiment, there are four sets of locking tongues 8. Each set of locking tongues 8 has a beveled structure on the rear side near the bottom. When the insert 5 is inserted forward into the rectangular through slot of the support column 7, the top edge of the front end of the insert 5 pushes the beveled structure of the locking tongue 8, so that the locking tongue 8 automatically lifts up to avoid the insert 5. This allows the insert 5, which is used to weld the frame 1, to be quickly and smoothly inserted into the through slot of the support column 7 to complete the locking connection between the frame 1 and the support column 7.
[0029] In this embodiment, there are four sets of push springs 9. One end of the push spring 9 is welded with a locking tongue 8, and the other end of the push spring 9 is welded with a cover plate 2. When the locking tongue 8 and the opening groove of the insert block 5 are aligned vertically, the push spring 9 drives the locking tongue 8 to penetrate into the opening groove of the insert block 5 through its own elastic force, thereby completing the automatic and rapid locking connection of the locking tongue 8 to the frame 1 and the support column 7.
[0030] The specific usage and function of this embodiment are as follows:
[0031] In the assembly of the condenser, the top and bottom ends of the heat dissipation fin plate 6 are first inserted into the grooves of the frame 1 and the cover plate 2, respectively. Then, the plug 5, which is welded to the frame 1, is aligned with the rear end of the through groove of the support column 7. The frame 1 is then manually pushed forward to insert the plug 5 into the through groove of the support column 7. At this time, the upper edge of the rear end of the plug 5 pushes the inclined structure of the locking tongue 8, causing the locking tongue 8 to move vertically upward along the square through groove wall of the support column 7, so that the locking tongue 8 automatically avoids the plug 5. When the opening groove of the plug 5 is aligned with the locking tongue 8, the push spring 9, through its own elastic force, drives the locking tongue 8 to insert into the opening groove of the plug 5. The locking tongue 8 locks the plug 5 in the rectangular through groove of the support column 7, completing the opposing clamping connection and installation of the heat dissipation fin plate 6 and the cooling heat exchange tube 3 by the support column 7 and the cover plate 2 in conjunction with the frame 1. During the condenser disassembly process, manually pull the handle 4. The handle 4 drives the rotating rod 10 and the locking block 11 to move upward against the elastic force of the push spring 9. When the bottom of the locking block 11 is higher than the bottom of the circular groove of the cover plate 2, manually rotate the handle 4 to drive the rotating rod 10 and the locking block 11 to rotate synchronously, so that the locking block 11 disengages from the upper side of the through hole opening groove of the cover plate 2 and fits against the bottom of the circular groove of the cover plate 2. At this time, the locking tongue 8 completely disengages from the opening groove of the insert 5. Then pull the frame 1 backward. At this time, the support column 7 separates from the frame 1. Then, the cooling heat exchange tube 3 can be taken out from the semi-circular opening groove of the support column 7. Finally, the damaged heat dissipation fin plate 6 can be taken out from the grooves of the frame 1 and the cover plate 2, thus completing the modular disassembly and separation of the cooling heat exchange tube 3 and the heat dissipation fin plate 6 in the condenser.
[0032] All the above components are installed, connected, or set up using common mechanical methods, such as welding, threaded connections, and screw connections. Furthermore, the specific structure, model, and coefficient indicators of all components are based on their own technologies, and any method that achieves the desired beneficial effect can be implemented. The cooling heat exchange tube 3 used above is a common component on the market; upon purchase and use, it only needs to be connected according to the instruction manual purchased with it, therefore, it will not be described in detail here.
[0033] The technical solution of this utility model is not limited to the scope of the embodiments of this utility model. All technical contents not described in detail in this utility model are known technologies.
Claims
1. A detachable modular condenser device, comprising a heat dissipation fin plate (6); the heat dissipation fin plate (6) is provided with a semi-circular opening groove extending from left to right, and a cooling heat exchange tube (3) is embedded in the semi-circular opening groove; characterized in that: It also includes a frame (1), a support column (7) and a rotating rod (10); the top and bottom of the support column (7) are connected by bolts to a cover plate (2); the front side of the frame (1) is welded with a plug (5), the frame (1) is a rectangular frame structure, the upper and lower sides of the rectangular frame structure of the frame (1) are provided with grooves, a heat dissipation fin plate (6) is inserted into the groove of the frame (1), the front side of the frame (1) is provided with a semi-circular groove, and a cooling heat exchange tube (3) is inserted into the semi-circular groove of the frame (1); the top of the rotating rod (10) is welded with a pull handle (4), the bottom of the rotating rod (10) is rotatably connected with a locking tongue (8), the upper side of the locking tongue (8) is welded with a push spring (9), and the outer side of the rotating rod (10) near the top is welded with a locking block (11).
2. The detachable modular condenser device as described in claim 1, characterized in that: The number of cover plates (2) is two sets. The cover plates (2) are symmetrically distributed on the top and bottom. Each set of cover plates (2) has fifty-three sets of rectangular opening grooves on the rear side. The top and bottom parts of the heat dissipation fin plate (6) are respectively inserted into the rectangular opening grooves of the cover plate (2). The upper side of the cover plate (2) is provided with a circular groove near the left and right ends. The center of the bottom of the circular groove of the cover plate (2) is provided with a through hole that runs vertically through the bottom. The inner side of each through hole is provided with a through opening groove that runs vertically through the bottom.
3. The detachable modular condenser device as described in claim 1, characterized in that: The number of the support pillars (7) is two sets. Each set of support pillars (7) has a rectangular through groove running through the front side. The upper side wall of the rectangular through groove has a square through groove. A locking tongue (8) is inserted in the square through groove of the support pillar (7). The rear side of the support pillar (7) has a semi-circular opening groove. A cooling heat exchange pipe (3) is embedded in the semi-circular opening groove of the support pillar (7).
4. The detachable modular condenser device as described in claim 1, characterized in that: The number of the inserts (5) is four sets, with each pair of inserts (5) symmetrically distributed vertically. Each set of inserts (5) has a through-hole groove, and a locking tongue (8) is embedded in the through-hole groove of the insert (5).
5. The detachable modular condenser device as described in claim 1, characterized in that: The number of the locking tongues (8) is four sets, and each set of locking tongues (8) has a sloping structure on the rear side near the bottom.
6. The detachable modular condenser device as described in claim 1, characterized in that: The number of push springs (9) is four sets. One end of the push spring (9) is welded with a locking tongue (8), and the other end of the push spring (9) is welded with a cover plate (2).