Fabric drying tower with rapid moisture removal function

By introducing a conical cover and an air pump into the fabric drying tower, combined with absorbent sponges and activated carbon packs, efficient heat and moisture recovery is achieved, solving the problems of heat and water waste and improving drying speed and energy efficiency.

CN224381965UActive Publication Date: 2026-06-19YI WU SHI YUAN YUAN ZHEN ZHI YOU XIAN GONG SI

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
YI WU SHI YUAN YUAN ZHEN ZHI YOU XIAN GONG SI
Filing Date
2025-07-01
Publication Date
2026-06-19

AI Technical Summary

Technical Problem

Existing fabric drying towers suffer from severe heat energy waste and low moisture recovery rates, resulting in energy waste, environmental pollution, and high energy costs.

Method used

A fabric drying tower with rapid dehumidification function was designed. The conical cover and the air pump work together to actively draw in high-temperature hot steam. Combined with moisture-absorbing sponge and activated carbon pack, it performs preliminary dehumidification. The steam temperature is increased by heating net to form a closed-loop heat cycle. At the same time, a two-stage moisture recovery system is constructed to collect distilled water through physical condensation and dynamic separation.

Benefits of technology

It improves thermal energy utilization, reduces water waste, lowers energy costs, reduces emissions of harmful substances, and increases drying speed and efficiency.

✦ Generated by Eureka AI based on patent content.

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  • Figure CN224381965U_ABST
    Figure CN224381965U_ABST
Patent Text Reader

Abstract

The utility model discloses a fabric drying tower with quick moisture removal function, including drying tower mechanism and the top cover mechanism of setting in the drying tower mechanism top, the one side of drying tower mechanism is provided with the moisture extraction mechanism, and the drying tower mechanism includes drying tower body, and the outside fixed setting of drying tower body has the connection long -tube, and the side of drying tower body below is provided with the through -hole. The utility model discloses through the synergies of conical cover and air -pump, and the steam of ascending is sucked to the connection long -tube, and after the U -shaped plate direction, enters the processing subassembly, in this process, steam first passes through the moisture absorption sponge and active carbon bag and carries out the preliminary dehumidification, and then through heating net, steam temperature is promoted to the reusable level, finally, the dry hot air is reintroduced drying tower bottom through the exhaust transverse hole, forms the closed -loop heat cycle, and this design can make the thermal efficiency utilization rate promotion, compares the traditional one -way exhaust type drying tower, and the drying speed is faster under the same power.
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Description

Technical Field

[0001] This utility model relates to the field of fabric drying tower technology, specifically a fabric drying tower with rapid dehumidification function. Background Technology

[0002] In patent application CN222418246U, different temperature zone drying sections are arranged from top to bottom. Each temperature zone drying section includes a drying chamber, an air outlet duct, a dust removal mechanism, an air source heat pump, and a hot air blower. The air outlet duct is arranged on the top of the drying chamber. The air inlet of the dust removal mechanism is connected to the air outlet duct, and the air outlet of the dust removal mechanism is connected to the air inlet of the heat pump. The air outlet of the heat pump is connected to the drying chamber via the hot air blower. A partition is arranged between the air outlet ducts of the different temperature zone drying sections to separate the different temperature zones. This utility model is used to solve the technical problems of existing drying towers having a single drying temperature, which does not match the drying temperature requirements of materials at different heights in the drying tower, and has high energy consumption.

[0003] In the aforementioned patents, most of the fabric drying towers suffer from severe heat energy waste and low moisture recovery rates during the drying process, resulting in significant energy waste, low drying efficiency, and increased energy costs. Furthermore, direct discharge of moisture leads to water resource waste, increases the burden of wastewater treatment, and exacerbates environmental pollution due to the emission of high-temperature and high-humidity exhaust gases. Utility Model Content

[0004] The purpose of this invention is to provide a fabric drying tower with rapid dehumidification function to solve the problems mentioned in the background art.

[0005] To achieve the above objectives, this utility model provides the following technical solution: a fabric drying tower with rapid dehumidification function, comprising a drying tower mechanism and a top cover mechanism disposed above the drying tower mechanism, wherein a dehumidification mechanism is disposed on one side of the drying tower mechanism, the drying tower mechanism includes a drying tower body, a connecting long pipe is fixedly disposed on the outside of the drying tower body, a through hole is opened on one side below the drying tower body, and an exhaust hole is disposed on the top of the drying tower body.

[0006] The top cover mechanism includes a conical cover disposed above the drying tower body. A connecting ring is fixedly connected to the lower end of the conical cover. A connecting through hole is opened on one side of the connecting ring. The connecting ring is fixedly connected to a connecting long pipe through the connecting through hole. A water-blocking ring is fixedly connected to the lower part of the inside of the conical cover.

[0007] Furthermore, the dehumidification mechanism includes a connecting shell fixedly connected to the lower outer side of the drying tower body. An air inlet is provided on the top of the connecting shell. The connecting shell is fixedly connected to a connecting long pipe through the air inlet. A connecting assembly is provided inside the connecting shell. An air pump is fixedly provided on the side of the connecting shell away from the drying tower body. A processing assembly is provided below the connecting assembly.

[0008] Furthermore, the connecting assembly includes an L-shaped baffle plate fixedly connected to the upper part of the connecting shell. A connecting hole is provided on the upper part of one side of the L-shaped baffle plate, and a U-shaped plate is fixedly connected to one side of the L-shaped baffle plate. The upper part of the U-shaped plate is fixedly connected to the upper part of the connecting shell, and a water outlet is provided on the lower part of the U-shaped plate. The position of the U-shaped plate corresponds to the position of the air inlet.

[0009] Furthermore, the air pump is fixedly equipped with an air extraction pipe, and the other end of the air extraction pipe is fixedly connected to the L-shaped water-blocking plate through a connecting pipe, with the connecting pipe corresponding to the position of the connecting hole.

[0010] Furthermore, the treatment component includes a fixed shell fixedly disposed at the lower end of the L-shaped water-blocking plate, a connecting short pipe fixedly connected to one end of the fixed shell, a moisture-absorbing sponge fixedly disposed inside the fixed shell near the connecting short pipe, and an activated carbon pack disposed on one side of the moisture-absorbing sponge.

[0011] Furthermore, an exhaust transverse hole is provided on the lower side of the fixed shell near the drying tower body, and a heating chamber is provided inside the fixed shell on the side near the exhaust transverse hole.

[0012] Furthermore, an exhaust pipe is fixedly installed on the air pump, and the other end of the exhaust pipe is fixedly connected to a connecting short pipe. A drainage pipe is provided on one side of the connecting shell, and the drainage pipe is located on one side of the L-shaped water-blocking plate.

[0013] Compared with the prior art, the beneficial effects of this utility model are: this fabric drying tower with rapid dehumidification function is reasonable and has the following advantages:

[0014] (1) A top cover mechanism is provided above the drying tower mechanism. The top cover mechanism is connected to a dehumidification mechanism through a connecting long pipe. The drying tower achieves efficient energy recovery and utilization through an innovative hot steam circulation design. When the high-temperature hot steam rises in the drying tower body, traditional equipment usually directly discharges this heat-rich steam, resulting in energy waste. However, this device actively draws the rising steam to the connecting long pipe through the synergistic effect of the conical cover and the air pump. After being guided by the U-shaped plate, it enters the processing component. In this process, the steam first undergoes preliminary dehumidification through the moisture-absorbing sponge and activated carbon bag. Then, the steam temperature is raised to a reusable level through the heating net. Finally, the dry hot air is reintroduced to the bottom of the drying tower through the exhaust horizontal hole, forming a closed-loop heat circulation. This design can improve the thermal energy utilization rate. Compared with the traditional unidirectional exhaust drying tower, the drying speed is faster under the same power.

[0015] (2) The device has a unique structural design that creates a two-stage water recovery system, which greatly reduces water waste. The first stage is physical condensation of the conical cover. When the steam comes into contact with the conical curved surface with a lower temperature, some water vapor is quickly condensed into liquid water. After being guided by the water baffle ring, it enters the connecting long pipe. The second stage is dynamic separation of the U-shaped plate. The high-speed airflow generates a centrifugal effect in the U-shaped plate, causing the atomized water droplets to collide with the plate wall and accumulate. They fall into the water storage chamber through the drain. The collected distilled water can be directly used for fabric washing or equipment cleaning through a special drainage pipe, reducing the factory's water expenditure. At the same time, the activated carbon pack can effectively adsorb volatile organic compounds, reducing the concentration of harmful substances in the exhaust gas. Attached Figure Description

[0016] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0017] Figure 2 This is a schematic diagram of the structure of the drying tower body of this utility model;

[0018] Figure 3 This is a schematic diagram of the top cover mechanism of this utility model;

[0019] Figure 4 This is a schematic diagram of the dehumidification mechanism of this utility model;

[0020] Figure 5 This is a schematic diagram of the structure of the connecting component of this utility model;

[0021] Figure 6 This is a schematic diagram of the structure of the processing component of this utility model.

[0022] In the diagram: 1. Drying tower mechanism; 11. Drying tower body; 12. Connecting long pipe; 2. Top cover mechanism; 21. Conical cover; 22. Connecting ring; 23. Connecting through hole; 24. Water baffle ring; 3. Dehumidification mechanism; 31. Connecting shell; 32. Air inlet; 33. Connecting assembly; 331. L-shaped water baffle plate; 332. Connecting hole; 333. U-shaped plate; 334. Drain outlet; 34. Processing assembly; 341. Fixed shell; 342. Connecting short pipe; 343. Exhaust horizontal hole; 344. Moisture-absorbing sponge; 345. Activated carbon bag; 346. Heating chamber; 35. Air pump. Detailed Implementation

[0023] 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.

[0024] Please see Figures 1-6 The present invention provides a technical solution as follows:

[0025] Example 1:

[0026] A fabric drying tower with rapid dehumidification function includes a drying tower mechanism 1 and a top cover mechanism 2 disposed above the drying tower mechanism 1. A dehumidification mechanism 3 is disposed on one side of the drying tower mechanism 1. The drying tower mechanism 1 includes a drying tower body 11. A connecting long pipe 12 is fixedly disposed on the outside of the drying tower body 11. A through hole is opened on one side below the drying tower body 11. An exhaust hole is disposed on the top of the drying tower body 11.

[0027] The top cover mechanism 2 includes a conical cover 21 disposed above the drying tower body 11. A connecting ring 22 is fixedly connected to the lower end of the conical cover 21. A connecting through hole 23 is provided on one side of the connecting ring 22. The connecting ring 22 is fixedly connected to the connecting long pipe 12 through the connecting through hole 23. A water-blocking ring 24 is fixedly connected to the lower part of the inside of the conical cover 21.

[0028] The dehumidification mechanism 3 includes a connecting shell 31 fixedly connected to the lower outer side of the drying tower body 11. An air inlet 32 ​​is provided on the upper part of the connecting shell 31. The connecting shell 31 is fixedly connected to the connecting long pipe 12 through the air inlet 32. A connecting component 33 is provided inside the connecting shell 31. An air pump 35 is fixedly provided on the side of the connecting shell 31 away from the drying tower body 11. A processing component 34 is provided below the connecting component 33.

[0029] The connecting component 33 includes an L-shaped baffle plate 331 fixedly connected to the upper part of the connecting shell 31. The L-shaped baffle plate 331 and the inner wall of the connecting shell 31 form a water storage chamber. A connecting hole 332 is opened on the upper side of one side of the L-shaped baffle plate 331. A U-shaped plate 333 is fixedly connected to one side of the L-shaped baffle plate 331. The upper end of the U-shaped plate 333 is fixedly connected to the upper part of the connecting shell 31. A drain outlet 334 is opened on the lower part of the U-shaped plate 333. The position of the U-shaped plate 333 corresponds to the position of the air inlet 32.

[0030] An air extraction pipe is fixedly installed on the air pump 35. The other end of the air extraction pipe is fixedly connected to the L-shaped water baffle 331 through a connecting pipe. The connecting pipe and the connecting hole 332 are positioned accordingly.

[0031] The treatment component 34 includes a fixed shell 341 fixedly installed at the lower end of the L-shaped water-proof plate 331. A connecting short pipe 342 is fixedly connected to one end of the fixed shell 341. A moisture-absorbing sponge 344 is fixedly installed inside the fixed shell 341 on the side near the connecting short pipe 342. An activated carbon pack 345 is installed on one side of the moisture-absorbing sponge 344.

[0032] An exhaust transverse hole 343 is provided on the lower side of the fixed shell 341 near the drying tower body 11. A heating chamber 346 is provided inside the fixed shell 341 on the side near the exhaust transverse hole 343. The exhaust transverse hole 343 corresponds to the through hole below the drying tower body 11.

[0033] An exhaust pipe is fixedly installed on the air pump 35, and the other end of the exhaust pipe is fixedly connected to the connecting short pipe 342. A drain pipe is provided on one side of the connecting shell 31, and the drain pipe is located on one side of the L-shaped baffle plate 331.

[0034] Working principle: During operation, the high-temperature steam generated by the drying tower body 11 rises naturally and enters the lower part of the conical cover 21 through the exhaust hole at the top of the tower body. The air pump 35 draws the airflow from the U-shaped plate 333 and the connecting long pipe 12 through the air extraction pipe. The connecting long pipe 12 draws the airflow from the conical cover 21, so that the hot steam in the conical cover 21 is drawn by the air pump 35 and discharged into the exhaust pipe. Then it is discharged from the exhaust pipe into the connecting short pipe 342, and then from the connecting short pipe 342 into the fixed shell 341. When the steam passes through the moisture-absorbing sponge 344 and the activated carbon pack 345, some of the moisture is absorbed by the moisture-absorbing sponge 344 and the activated carbon pack 345. After passing through the activated carbon pack 345, the steam enters the heating chamber 346 and is heated by the heating mesh in the heating chamber 346, which evaporates the residual moisture in the steam and heats the airflow. Finally, it enters the drying tower body 11 through the exhaust horizontal hole 343 and the through hole at the bottom of the drying tower body 11 to continue heating the fabric.

[0035] When hot steam drifts upwards into the conical cover 21 through the exhaust port above the drying tower body 11, some of the hot steam comes into contact with the inner wall of the conical cover 21 and condenses into water droplets. The water droplets flow along the inclined surface of the conical cover 21 and encounter the water-blocking ring 24. Then, they drip from the water-blocking ring 24 onto the shell above the drying tower body 11. As the water continues to flow along the inclined surface of the shell above the drying tower body 11, it is blocked by the connecting ring 22 and enters the connecting long pipe 12 through the connecting through hole 23. Then, it flows into the connecting shell 31 from the connecting long pipe 12 and drips into the U-shaped plate 333. As more and more water accumulates, it drips from the drain 334 into the cavity formed by the L-shaped baffle plate 331 and the inner wall of the connecting shell 31, collecting the distilled water. The distilled water on the L-shaped baffle plate 331 is discharged from the drain pipe for use in rinsing fabrics and cleaning equipment.

[0036] 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. A fabric drying tower with rapid dehumidification function, comprising a drying tower mechanism (1) and a top cover mechanism (2) disposed above the drying tower mechanism (1), wherein a dehumidification mechanism (3) is disposed on one side of the drying tower mechanism (1), characterized in that: The drying tower mechanism (1) includes a drying tower body (11), a connecting long pipe (12) is fixedly installed on the outside of the drying tower body (11), a through hole is opened on one side below the drying tower body (11), and an exhaust hole is provided on the top of the drying tower body (11). The top cover mechanism (2) includes a conical cover (21) disposed above the drying tower body (11). A connecting ring (22) is fixedly connected to the lower end of the conical cover (21). A connecting through hole (23) is opened on one side of the connecting ring (22). The connecting ring (22) is fixedly connected to the connecting long pipe (12) through the connecting through hole (23). A water baffle ring (24) is fixedly connected to the lower part of the inside of the conical cover (21).

2. The fabric drying tower with rapid dehumidification function according to claim 1, characterized in that: The dehumidification mechanism (3) includes a connecting shell (31) fixedly connected to the lower outer side of the drying tower body (11). An air inlet (32) is provided on the upper part of the connecting shell (31). The connecting shell (31) is fixedly connected to the connecting long pipe (12) through the air inlet (32). A connecting component (33) is provided inside the connecting shell (31). An air pump (35) is fixedly provided on the side of the connecting shell (31) away from the drying tower body (11). A processing component (34) is provided below the connecting component (33).

3. A fabric drying tower with rapid dehumidification function according to claim 2, characterized in that: The connecting assembly (33) includes an L-shaped baffle plate (331) fixedly connected to the upper part of the connecting shell (31). A connecting hole (332) is provided on the upper part of one side of the L-shaped baffle plate (331). A U-shaped plate (333) is fixedly connected to one side of the L-shaped baffle plate (331). The upper end of the U-shaped plate (333) is fixedly connected to the upper part of the connecting shell (31). A drain outlet (334) is provided on the lower part of the U-shaped plate (333). The position of the U-shaped plate (333) corresponds to the position of the air inlet (32).

4. A fabric drying tower with rapid dehumidification function according to claim 3, characterized in that: The air pump (35) is fixedly equipped with an air extraction pipe. The other end of the air extraction pipe is fixedly connected to the L-shaped water baffle (331) through a connecting pipe. The connecting pipe is positioned corresponding to the connecting hole (332).

5. A fabric drying tower with rapid dehumidification function according to claim 3, characterized in that: The processing component (34) includes a fixed shell (341) fixedly installed at the lower end of the L-shaped water-proof plate (331). A connecting short pipe (342) is fixedly connected to one end of the fixed shell (341). A moisture-absorbing sponge (344) is fixedly installed inside the fixed shell (341) on the side near the connecting short pipe (342). An activated carbon bag (345) is installed on one side of the moisture-absorbing sponge (344).

6. A fabric drying tower with rapid dehumidification function according to claim 5, characterized in that: The fixed shell (341) has an exhaust horizontal hole (343) on the side below the drying tower body (11), and a heating chamber (346) is provided inside the fixed shell (341) on the side near the exhaust horizontal hole (343).

7. A fabric drying tower with rapid dehumidification function according to claim 2, characterized in that: An exhaust pipe is fixedly installed on the air pump (35), and the other end of the exhaust pipe is fixedly connected to the connecting short pipe (342). A drainage pipe is provided on one side of the connecting shell (31), and the drainage pipe is located on one side of the L-shaped baffle plate (331).