A high-efficiency ceramic special-shaped carrier runner device for dehumidification

By introducing a humidity detection sensor and controller into the ceramic irregular carrier rotating device, combined with the first and second hot air ducts and the shielding mechanism, the thermal desorption area is dynamically adjusted, which solves the problem of low dehumidification efficiency of existing devices and achieves a high-efficiency and energy-saving dehumidification effect.

CN224498642UActive Publication Date: 2026-07-14SHUNXINYI NEW MATERIALS (JIANGXI) CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHUNXINYI NEW MATERIALS (JIANGXI) CO LTD
Filing Date
2025-03-13
Publication Date
2026-07-14

AI Technical Summary

Technical Problem

Existing ceramic irregular carrier rotor devices are difficult to adjust the thermal desorption zone according to air humidity, resulting in low dehumidification efficiency and limited applicability.

Method used

It employs a first hot air duct, a second hot air duct, a shielding mechanism, and a variable speed motor. By adjusting the opening and closing of the hot air duct and the air speed through a humidity detection sensor and a controller, it achieves dynamic adjustment of the heat desorption area and improves dehumidification efficiency.

Benefits of technology

The thermal desorption zone is dynamically adjusted under different humidity conditions, which improves dehumidification efficiency, saves energy and is environmentally friendly, and has strong adaptability.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model relates to the technical field of runner dehumidification equipment, and disclose a kind of ceramic special-shaped carrier runner device for high efficiency dehumidification;Including support frame, the support frame inner chamber is equipped with runner disc, further include: the treatment pipeline of being arranged in the surface of support frame one side, the filter plate is slidably connected with the clamping of the treatment pipeline far from support frame one end top surface, the side surface of the treatment pipeline is equipped with limiting mechanism;First hot air pipe being arranged below the treatment pipeline, the first hot air pipe one side is equipped with second hot air pipe, the second hot air pipe is close to the side of first hot air pipe and is equipped with shielding mechanism, the utility model is provided with first hot air pipe, second hot air pipe, shielding mechanism and variable speed motor, when air humidity is too high in treatment pipeline, shielding plate can be stretched out from second hot air pipe as required, so that hot air is blown out in the inside of two hot air pipes, and the thermal desorption efficiency of runner disc is improved.
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Description

Technical Field

[0001] This utility model relates to the technical field of rotary dehumidification equipment, specifically a ceramic irregular carrier rotary device for high-efficiency dehumidification. Background Technology

[0002] The principle of rotary dehumidifier is that a honeycomb-shaped rotary wheel rotates through the treatment zone and the regeneration zone to dehumidify. In the treatment zone, it absorbs moisture from the air, and when it enters the regeneration zone, the hot air removes the moisture. This cycle repeats to achieve the dehumidification effect.

[0003] Generally, the dehumidifier wheel is made of a ceramic carrier and activated silica gel. The activated silica gel can absorb moisture, and the moisture will leave the activated silica gel under the drying of hot air. In order to increase the surface area of ​​the wheel, anisotropic ceramic carriers can be combined with activated silica gel. However, in actual applications, it is difficult to adjust the area of ​​the wheel for thermal desorption according to the humidity of the air when performing thermal desorption using dehumidifier wheel devices with anisotropic ceramic carriers. Its applicability is generally limited and it is not conducive to widespread use. Utility Model Content

[0004] The purpose of this invention is to provide a high-efficiency dehumidification ceramic irregular carrier rotor device to solve the problem of difficulty in adjusting the heat desorption area of ​​the rotor according to the humidity of the air.

[0005] To achieve the above objectives, this utility model provides the following technical solution: a high-efficiency dehumidification ceramic irregular-shaped carrier rotor device, including a support frame, wherein the inner cavity of the support frame is provided with a rotor disk, and further comprising:

[0006] A processing pipe is provided on one side surface of the support frame. A filter plate is slidably connected to the top surface of the processing pipe at the end away from the support frame. A limiting mechanism is provided on one side surface of the processing pipe.

[0007] A first hot air duct is installed below the processing pipe. A second hot air duct is provided on one side of the first hot air duct. A shielding mechanism is provided on the side of the second hot air duct close to the first hot air duct. The shielding mechanism includes a reduction motor fixedly connected to the surface of one side of the second hot air duct by a connecting rod. A drive gear is provided above the reduction motor. A toothed plate is provided on the outer surface of the drive gear. A shielding plate is fixedly connected to one side of the toothed plate.

[0008] A heating cover is installed at one end of the first hot air pipe and the second hot air pipe. One end of the heating cover is fixedly connected to a blower plate through a connecting pipe, and one end of the blower plate is fixedly connected to a variable speed motor.

[0009] Preferably, the inner cavity of the support frame is equipped with a servo motor, the top and bottom ends of the servo motor are fixedly connected to the support frame by a connecting rod, and the output end of the servo motor is fixedly connected to the rotary disk.

[0010] Preferably, the limiting mechanism includes a limiting box fixedly connected to both sides of the processing pipe, a square plate being slidably connected to the inner cavity of the limiting box, a limiting post being fixedly connected through the side of the square plate away from the processing pipe, and a limiting spring being fixedly connected to the side of the square plate away from the processing pipe.

[0011] Preferably, both sides of the filter plate are fixedly connected with insert strips, the insert strips have a square horizontal cross-section, the top surface of the support frame is provided with a slot that matches the size of the insert strips, and the two insert strips are provided with limiting holes that match the size of the limiting posts on the side surface near the limiting box.

[0012] Preferably, the bottom end of the drive gear disk is fixedly connected to the output end of the reduction motor, and the outer surface of the drive gear disk is meshed with the gear plate.

[0013] Preferably, the second hot air duct has a slot that matches the structural size of the baffle plate through the surface of the side closest to the first hot air duct. The baffle plate has a bonding plate fixedly connected to the side of the side away from the drive gear plate. Both the outer surfaces of the baffle plate and the bonding plate are coated with a sealing soft layer.

[0014] Preferably, the second hot air duct has a slot that matches the size of the toothed plate structure on the surface of the side closest to the first hot air duct, and the toothed plate matches the size of the bonding plate structure.

[0015] Preferably, there are two heating covers, and each of the two heating covers has an electric heating wire fixedly connected to its inner cavity.

[0016] Preferably, the inner cavity of the blower plate is provided with blower blades, and one end of the blower blades is fixedly connected to the output end of the variable speed motor.

[0017] Preferably, a humidity detection sensor is fixedly connected through the top surface of the processing pipe, and a control box is fixedly connected to one side surface of the support frame, with a controller installed inside the control box.

[0018] Compared with the prior art, the beneficial effects of this utility model are as follows:

[0019] This invention incorporates a first hot air duct, a second hot air duct, a shielding mechanism, and a variable speed motor. When the air humidity in the processing pipeline is too high, the shield can extend from the second hot air duct as needed, allowing hot air to be blown out from both hot air ducts. This improves the thermal desorption efficiency of the rotating disc, thereby increasing the dehumidification efficiency. Furthermore, when the air humidity in the processing pipeline is low, the shield blocks the second hot air duct, allowing hot air to be blown out from the first hot air duct for thermal desorption of the rotating disc, resulting in greater energy efficiency and environmental friendliness. Attached Figure Description

[0020] Figure 1 A schematic diagram of a preferred embodiment of the high-efficiency dehumidification ceramic irregular carrier rotor device provided by this utility model;

[0021] Figure 2 A structural schematic diagram showing the internal details of the support frame provided by this utility model;

[0022] Figure 3 A schematic diagram showing the internal details of the shielding mechanism and heating cover provided by this utility model;

[0023] Figure 4 A schematic diagram showing the details of the limiting mechanism provided by this utility model.

[0024] In the diagram: 1. Support frame; 2. Rotary disc; 3. Processing pipe; 4. Filter plate; 5. Limiting mechanism; 51. Limiting box; 52. Square plate; 53. Limiting post; 54. Limiting spring; 6. First hot air pipe; 7. Second hot air pipe; 8. Shielding mechanism; 81. Gear motor; 82. Drive gear plate; 83. Gear plate; 84. Shielding plate; 9. Heating cover; 10. Blower plate; 11. Variable speed motor; 12. Servo motor; 13. Clip strip; 14. Adhesive plate; 15. Electric heating wire; 16. Blower fan blade; 17. Humidity detection sensor; 18. Control box. Detailed Implementation

[0025] 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.

[0026] Please see Figure 1-4As shown, a high-efficiency dehumidification ceramic irregularly shaped carrier rotary device includes a support frame 1. A servo motor 12 is installed inside the support frame 1, with its top and bottom ends fixedly connected to the support frame 1 via connecting rods. A rotary disk 2 is installed inside the support frame 1. The rotary disk 2 is an irregularly shaped ceramic carrier and active silica gel composite. The output end of the servo motor 12 is fixedly connected to the rotary disk 2, driving the rotary disk 2 to rotate. A processing pipe 3 is installed on one side surface of the support frame 1, with a humidity detection sensor 17 fixedly connected through its top surface. A control device is fixedly connected to one side surface of the support frame 1. The control box 18 has a controller inside, which is a PLC controller or a microcontroller. The humidity detection sensor 17 senses and processes the humidity information inside the pipe 3 and transmits it to the controller for processing and analysis via wires. The controller increases or decreases the speed of the variable speed motor 11 based on the humidity information and controls the start and stop of the electric heating wires 15 inside the two heating covers 9. These are well-known technical means and will not be described in detail here. A filter plate 4 is slidably connected to the top surface of the end of the processing pipe 3 away from the support frame 1. The surface of the filter plate 4 has filter holes through it. A limiting mechanism 5 is provided on one side surface of the processing pipe 3.

[0027] like Figure 4 As shown, the limiting mechanism 5 includes a limiting box 51 fixedly connected to both sides of the processing pipe 3. A square plate 52 is slidably connected to the inner cavity of the limiting box 51. A limiting post 53 is fixedly connected through the side of the square plate 52 away from the processing pipe 3. Both ends of the limiting post 53 are movably connected through the limiting box 51. A limiting spring 54 is fixedly connected to the side of the square plate 52 away from the processing pipe 3. One end of the limiting spring 54 is fixedly connected to the square plate 52. Pulling the limiting post 53 protruding from one end of the limiting box 51 can drive... When the square plate 52 moves, the limiting spring 54 deforms, allowing the filter plate 4 to be removed and replaced. Both sides of the filter plate 4 are fixedly connected with insert strips 13. The insert strips 13 have a square horizontal cross-section. The top surface of the support frame 1 has a slot that matches the structural dimensions of the insert strips 13. The two insert strips 13 have limiting holes on the side of the limiting box 51 that match the structural dimensions of the limiting post 53. The limiting post 53 is inserted into the limiting hole to limit the position of the insert strips 13, so that the filter plate 4 is locked at one end of the processing pipe 3.

[0028] like Figure 1 and Figure 3As shown, a first hot air duct 6 is located below the processing duct 3. A second hot air duct 7 is located on one side of the first hot air duct 6. A shielding mechanism 8 is located on the side of the second hot air duct 7 near the first hot air duct 6. The shielding mechanism 8 includes a reduction motor 81 fixedly connected to the surface of one side of the second hot air duct 7 via a connecting rod. A drive gear 82 is located above the reduction motor 81. A toothed plate 83 is located on the outer surface of the drive gear 82. The bottom end of the drive gear 82 is fixedly connected to the output end of the reduction motor 81. The outer surface of the drive gear 82 is meshed with the toothed plate 83. A shielding plate 84 is fixedly connected to one side of the toothed plate 83. A through-hole is formed on the surface of the second hot air duct 7 near the first hot air duct 6. The shield 84 has a slot that matches its structural dimensions. A bonding plate 14 is fixedly connected to the side surface of the shield 84 away from the drive gear plate 82. Both the outer surfaces of the shield 84 and the bonding plate 14 are coated with a sealing soft layer made of rubber. The second hot air pipe 7 has a slot that matches its structural dimensions on the side surface of the second hot air pipe 6. The toothed plate 83 and the bonding plate 14 have matching structural dimensions. After the shield 84 extends out of the second hot air pipe 7, the bonding plate 14 is attached and slidably connected to the slot in the second hot air pipe 7 that matches the structural dimensions of the toothed plate 83, so as to prevent air leakage when the second hot air pipe 7 blows out hot air.

[0029] like Figure 3 A heating cover 9 is installed at one end of the first hot air pipe 6 and the second hot air pipe 7. There are two heating covers 9. An electric heating wire 15 is fixedly connected to the inner cavity of each heating cover 9. A blower plate 10 is fixedly connected to one end of the heating cover 9 through a connecting pipe. A blower blade 16 is provided in the inner cavity of the blower plate 10. One end of the blower blade 16 is fixedly connected to the output end of the variable speed motor 11. The variable speed motor 11 drives the rotation of the blower blade 16, blowing out the heat generated by the electric heating wire 15 in the heating cover 9 to form hot air.

[0030] Working principle: During use, air enters the support frame 1 through the processing pipe 3. The filter plate 4 filters the air. The start of the servo motor 12 drives the rotation of the rotating disk 2. The active silica gel in the rotating disk 2 absorbs the moisture in the air. At this time, the humidity detection sensor 17 senses and processes the humidity information in the pipe 3. If the humidity is low, the start of the variable speed motor 11 is controlled, which in turn controls the start of the electric heating wire 15 on one side of the first hot air pipe 6. The variable speed motor 11 drives the fan blades 16 to rotate, blowing out hot air with the heat generated by the electric heating wire 15, which then removes the moisture absorbed by the active silica gel in the rotating disk 2. In the process of thermal desorption, if the humidity in the treatment pipe 3 is too high, the speed reduction motor 81 is started to drive the rotation of the drive gear plate 82, which in turn drives the movement of the gear plate 83 and the baffle plate 84. The baffle plate 84 is gradually extended out of the second hot air pipe 7 until the bonding plate 14 on the baffle plate 84 is attached to and slidably connected to the inner surface of the second hot air pipe 7. At this time, the speed of the variable speed motor 11 is increased and the electric heating wire 15 on one side of the second hot air pipe 7 is turned on. At this time, hot air will be blown out from both the second hot air pipe 7 and the first hot air pipe 6 to perform thermal desorption treatment on the rotating disc 2, thereby improving the dehumidification efficiency of the device.

[0031] It should be noted that, in this document, relational terms such as "first" and "second" are used only to distinguish one entity or operation from another, and do not necessarily require or imply any such actual relationship or order between these entities or operations. Furthermore, the terms "comprising," "including," or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such a process, method, article, or apparatus. Without further limitations, an element defined by the phrase "comprising one..." does not exclude the presence of other identical elements in the process, method, article, or apparatus that includes said element.

[0032] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A high-efficiency dehumidification ceramic irregular carrier rotating device, comprising a support frame (1), wherein the inner cavity of the support frame (1) is provided with a rotating disk (2), characterized in that, Also includes: A processing pipe (3) is provided on one side surface of the support frame (1). A filter plate (4) is slidably connected to the top surface of the end of the processing pipe (3) away from the support frame (1). A limiting mechanism (5) is provided on one side surface of the processing pipe (3). A first hot air duct (6) is provided below the processing pipe (3). A second hot air duct (7) is provided on one side of the first hot air duct (6). A shielding mechanism (8) is provided on the side of the second hot air duct (7) close to the first hot air duct (6). The shielding mechanism (8) includes a reduction motor (81) fixedly connected to the surface of one side of the second hot air duct (7) by a connecting rod. A drive gear disk (82) is provided above the reduction motor (81). A toothed plate (83) is provided on the outer surface of the drive gear disk (82). A shielding plate (84) is fixedly connected to one side of the toothed plate (83). A heating cover (9) is provided at one end of the first hot air pipe (6) and the second hot air pipe (7). One end of the heating cover (9) is fixedly connected to a blower plate (10) through a connecting pipe. One end of the blower plate (10) is fixedly connected to a variable speed motor (11).

2. The high-efficiency dehumidification ceramic irregular carrier rotor device according to claim 1, characterized in that: The inner cavity of the support frame (1) is equipped with a servo motor (12). The top and bottom ends of the servo motor (12) are fixedly connected to the support frame (1) through connecting rods. The output end of the servo motor (12) is fixedly connected to the turntable (2).

3. The high-efficiency dehumidification ceramic irregular carrier rotor device according to claim 1, characterized in that: The limiting mechanism (5) includes a limiting box (51) fixedly connected to both sides of the processing pipe (3). A square plate (52) is slidably connected to the inner cavity of the limiting box (51). A limiting post (53) is fixedly connected through the side of the square plate (52) away from the processing pipe (3). A limiting spring (54) is fixedly connected to the side of the square plate (52) away from the processing pipe (3).

4. The high-efficiency dehumidification ceramic irregular carrier rotor device according to claim 3, characterized in that: Both sides of the filter plate (4) are fixedly connected with insert strips (13). The insert strips (13) have a square structure in horizontal cross section. The top surface of the support frame (1) is provided with a slot that matches the structural size of the insert strips (13). The two insert strips (13) are provided with a limiting hole that matches the structural size of the limiting post (53) on the side surface of the limiting box (51).

5. The high-efficiency dehumidification ceramic irregular carrier rotor device according to claim 1, characterized in that: The bottom end of the drive gear disk (82) is fixedly connected to the output end of the reduction motor (81), and the outer surface of the drive gear disk (82) is meshed with the gear plate (83).

6. The high-efficiency dehumidification ceramic irregular carrier rotor device according to claim 1, characterized in that: The second hot air duct (7) has a slot that matches the structural size of the baffle plate (84) through the surface of the side closest to the first hot air duct (6). The baffle plate (84) has a bonding plate (14) fixedly connected to the side surface of the side away from the drive gear plate (82). Both the outer surfaces of the baffle plate (84) and the bonding plate (14) are coated with a sealing soft layer.

7. The high-efficiency dehumidification ceramic irregular carrier rotor device according to claim 6, characterized in that: The second hot air duct (7) has a slot that matches the structural dimensions of the toothed plate (83) through its surface near the first hot air duct (6), and the toothed plate (83) matches the structural dimensions of the bonding plate (14).

8. The high-efficiency dehumidification ceramic irregular carrier rotor device according to claim 1, characterized in that: There are two heating covers (9), and electric heating wires (15) are fixedly connected to the inner cavities of both heating covers (9).

9. The high-efficiency dehumidification ceramic irregular carrier rotor device according to claim 1, characterized in that: The inner cavity of the blower plate (10) is provided with a blower blade (16), and one end of the blower blade (16) is fixedly connected to the output end of the variable speed motor (11).

10. The high-efficiency dehumidification ceramic irregular carrier rotor device according to claim 1, characterized in that: A humidity detection sensor (17) is fixedly connected through the top surface of the processing pipe (3), and a control box (18) is fixedly connected to one side surface of the support frame (1). The control box (18) has a controller inside.