Horizontal zeolite wheel device
By adopting a horizontal design and a multi-point support structure in the zeolite rotor device, the deformation problem caused by insufficient support points was solved, thus achieving stable rotation of the rotor and extending its service life.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- ANHUI OXYGEN ENVIRONMENTAL PROTECTION TECH CO LTD
- Filing Date
- 2025-08-14
- Publication Date
- 2026-06-23
Smart Images

Figure CN224388450U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of waste gas treatment technology, specifically a horizontal zeolite rotor device. Background Technology
[0002] Zeolite rotors are a highly efficient adsorption and concentration technology widely used in industrial waste gas treatment, especially for large-volume, low-concentration volatile organic compound treatment.
[0003] The core principle of a zeolite rotor is to utilize zeolite (molecular sieve) as an adsorbent, and to achieve continuous adsorption, desorption, and cooling regeneration processes through a continuously rotating honeycomb rotor. Specifically, the zeolite rotor is a rotating wheel filled with adsorbent, divided into three zones: an adsorption zone, a regeneration zone, and a cooling zone. VOCs waste gas is introduced into the adsorption zone by a blower, where the organic pollutants are adsorbed, and the gas is purified and discharged. Subsequently, the adsorbent rotates to the regeneration zone, where, during contact with high-temperature air, VOCs are desorbed and flow out with the regeneration air, simultaneously regenerating the adsorbent. The regenerated adsorbent is first cooled in the cooling zone and then rotates back to the adsorption zone for re-adsorption. As the rotor rotates, the adsorbent periodically undergoes adsorption, desorption, and cooling, achieving the purification of organic waste gas.
[0004] However, in practical applications, commonly used zeolite rotors are typically supported on an outer casing by a shaft at the center of the rotor. The motor-driven equipment directly drives the zeolite rotor to rotate through this central shaft. Due to the limited number of support points and insufficient support strength, the rotor is prone to deformation due to its own weight and other factors, thus affecting its sealing performance and service life. Utility Model Content
[0005] The purpose of this invention is to provide a horizontal zeolite rotor device to solve the problem of poor structural stability of current zeolite rotors.
[0006] To achieve the above objectives, this utility model provides the following technical solution: a horizontal zeolite rotor device, comprising a housing, a rotor assembly rotatably mounted within the housing, and a driving component for driving the rotor assembly to rotate. The supporting component includes a supporting shaft, a supporting gear fitted in the middle of the supporting shaft, and supporting rollers fitted on the supporting shaft and located on the front and rear sides of the supporting gear. The front and rear ends of the supporting shaft are respectively rotatably sleeved on the front and rear walls of the housing near the four corners. An annular groove is provided in the middle of the outer peripheral wall of the rotor assembly, and an external gear ring that meshes and matches with the supporting gear is fixed in the annular groove. An annular groove is provided on the outer peripheral wall of the rotor assembly corresponding to the position of the supporting roller, and the supporting roller is rotatably engaged in the annular groove.
[0007] Preferably, the front and rear walls of the housing are respectively provided with circular openings in the center, and a horizontal beam is provided in the middle of the circular opening. A bearing seat is respectively fitted in the center of the horizontal beam. The axis of the rotating wheel assembly is provided with a central shaft body whose front and rear ends are respectively rotatably fitted with the bearing seat. The front and rear walls of the housing are respectively fitted with bearing seats two that are rotatably fitted with the ends of the support shaft near the four corners.
[0008] Preferably, the rotating wheel assembly includes an annular housing, a central column disposed at the axis of the annular housing, a plurality of partitions radially fixedly connected between the inner peripheral wall of the annular housing and the outer peripheral wall of the central column and dividing the inner cavity of the annular housing into a pair of fan-shaped cavities, and zeolite units disposed between two adjacent partitions. The annular groove and the annular wheel groove are respectively disposed on the outer peripheral wall of the annular housing, and the central shaft is fitted onto the axis of the central column.
[0009] Preferably, a side slot is provided in the middle of one side wall of the housing, and the driving component includes a chassis fixed to the outer side wall of the housing and corresponding to the side slot, a drive gear rotatably installed in the chassis and meshing with the external gear ring through the side slot, and a motor fixed to the front wall of the chassis and used to drive the drive gear to rotate.
[0010] Preferably, diagonal bracing rods are fixedly connected radially between the two sides of the middle part of the bottom surface of the crossbeam and the inner peripheral wall of the circular opening.
[0011] Preferably, the annular shell, partition, central shaft, and central column are all made of stainless steel.
[0012] Preferably, the front and rear walls of the inner cavity of the box are respectively fixed with rings that are rotatably fitted and matched with the annular shell at the positions corresponding to the circular opening.
[0013] Compared with the prior art, the beneficial effects of this utility model are:
[0014] This utility model relates to a horizontal zeolite rotor device, which adds four support members to support the top and bottom sides of the rotor assembly, thereby improving the support stability of the rotor assembly, ensuring the smooth and stable rotation of the rotor assembly, and avoiding the problem of the rotor assembly being easily deformed due to insufficient support. Attached Figure Description
[0015] Figure 1 This is a three-dimensional structural diagram of the entire utility model;
[0016] Figure 2 This is a three-dimensional structural diagram of the box body of this utility model;
[0017] Figure 3 This is a three-dimensional structural diagram of the rotary wheel assembly of this utility model;
[0018] Figure 4 This is a three-dimensional structural diagram of the driving component of this utility model;
[0019] Figure 5 This is a three-dimensional structural diagram of the support component of this utility model.
[0020] In the diagram: 1-Box body; 1.1-Circular opening; 1.2-Crossbeam; 1.3-Ring body; 1.4-Diagonal brace; 1.5-Shaft seat one; 1.6-Shaft seat two; 1.7-Side groove;
[0021] 2-Rotator assembly; 2.1-Annular housing; 2.1.1-Annular groove; 2.1.2-External gear ring; 2.1.3-Annular groove; 2.2-Baffle; 2.3-Zeolite unit; 2.4-Central shaft; 2.5-Central column;
[0022] 3-Drive component; 5.1-Chassis; 5.2-Drive gear; 5.3-Motor;
[0023] 4-Support component; 4.1-Support shaft; 4.2-Support gear; 4.3-Support roller. Detailed Implementation
[0024] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0025] Please see Figure 1-5 This utility model provides a technical solution: a horizontal zeolite rotor device, wherein a circular opening 1.1 is centrally located on the front and rear walls of the housing 1, and a transverse beam 1.2 extending laterally is provided in the center of the circular opening 1.1. A bearing seat 1.5 is fitted at the center of the crossbeam 1.2. In addition, bearing seats 1.6 are fitted near the four corners of the front and rear walls of the housing 1. To improve the overall rigidity and support strength of the crossbeam 1.2, diagonal bracing rods 1.4 are radially fixedly connected to the two sides of the bottom center of the crossbeam 1.2 and the inner peripheral wall of the circular opening 1.1. Rings 1.3 are fixedly fixed on the front and rear walls of the inner cavity of the housing 1 at positions corresponding to the circular opening 1.1, and a side groove 1.7 is provided in the center of one side wall of the housing 1.
[0026] The impeller assembly 2 includes an annular housing 2.1, a central column 2.5 located at the axis of the annular housing 2.1, multiple partitions 2.2 radially fixed between the inner peripheral wall of the annular housing 2.1 and the outer peripheral wall of the central column 2.5, dividing the inner cavity of the annular housing 2.1 into a pair of sector-shaped cavities, and zeolite units 2.3 located between adjacent partitions 2.2. An annular groove 2.1.1 is located in the middle of the outer peripheral wall of the annular housing 2.1, and an annular wheel groove 2.1.3 is located on the outer peripheral wall of the annular housing 2.1, positioned at the front and rear sides of the annular groove 2.1.1. A central shaft 2.4 is fitted onto the axis of the central column 2.5. An external gear ring 2.1.2 is fixed inside the annular groove 2.1.1. The front and rear ends of the annular housing 2.1 are rotatably sleeved with the annular body 1.3, and the front and rear ends of the central shaft 2.4 are rotatably sleeved with the bearing seat 1.5. The annular housing 2.1, partition 2.2, central shaft 2.4, and central column 2.5 are all made of stainless steel. The annular housing 2.1 and central column 2.5 have sufficient wall thickness, the central column 2.5 has sufficient outer diameter, and the overall thickness of partition 2.2 is increased to ensure the overall strength and rigidity of the rotor assembly 2.
[0027] The driving component 3 includes a housing 5.1 fixed to the outer wall of the housing 1 and corresponding to the side slot 1.7, a drive gear 5.2 rotatably mounted inside the housing 5.1 and meshing with the external gear ring 2.1.2 through the side slot 1.7, and a motor 5.3 fixed to the front wall of the housing 5.1 for driving the drive gear 5.2 to rotate. That is, the motor 5.3 drives the drive gear 5.2 to rotate, and the drive gear 5.2 meshes with the external gear ring 2.1.2 to achieve the effect of driving the drive component 3 to drive the entire rotating wheel assembly 2 to rotate in the housing 1.
[0028] The support component 4 includes a support shaft 4.1, a support gear 4.2 fitted in the middle of the support shaft 4.1, and support rollers 4.3 fitted on the support shaft 4.1 and located on the front and rear sides of the support gear 4.2. The front and rear ends of the support shaft 4.1 are respectively rotatably fitted onto the corresponding bearing seat 1.6. The support rollers 4.3 are rotatably engaged in the annular groove 2.1.3. That is, for the entire rotating wheel assembly 2, in addition to the rotational support of the central shaft 2.4 by the bearing seat 1.5, the four support components 4 effectively support the top and bottom sides of the annular shell 2.1. Through multi-point support, the overall support effect of the rotating wheel assembly 2 is improved, thereby ensuring the smooth and stable rotation of the rotating wheel assembly 2 and avoiding the problem of deformation of the rotating wheel assembly 2 due to insufficient support.
[0029] 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 process, method, article, or apparatus.
[0030] 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 horizontal zeolite rotor device, comprising a housing (1), a rotor assembly (2) rotatably mounted within the housing (1), and a driving component (3) for driving the rotor assembly (2) to rotate, characterized in that, Also includes: Support member (4), the support member (4) includes a support shaft (4.1), a support gear (4.2) fitted in the middle of the support shaft (4.1), and support rollers (4.3) fitted in the support shaft (4.1) and located on the front and rear sides of the support gear (4.2); The front and rear ends of the support shaft (4.1) are respectively rotatably sleeved on the front and rear walls of the housing (1) near the four corners. The outer peripheral wall of the wheel assembly (2) is provided with an annular groove. 2.1.1) An external gear ring (2.1.2) that meshes with and matches the support gear (4.2) is fixed in the annular groove (2.1.1). The outer peripheral wall of the rotating wheel assembly (2) is provided with an annular groove (2.1.3) corresponding to the position of the support roller (4.3). The support roller (4.3) is rotatably engaged in the annular groove (2.1.3).
2. The horizontal zeolite rotor device according to claim 1, characterized in that: The box body (1) has a circular opening (1.1) in the center of the front and rear walls respectively. A horizontal beam (1.2) extending in the middle of the circular opening (1.1) is provided. A bearing seat (1.5) is fitted in the center of the horizontal beam (1.2). A central shaft (2.4) is provided at the axis of the rotating wheel assembly (2), with its front and rear ends respectively corresponding to the bearing seat (1.5) for rotational connection. Bearing seat (1.6) matching the end of the support shaft (4.1) is fitted near the four corners of the front and rear walls of the box body (1).
3. The horizontal zeolite rotor device according to claim 2, characterized in that: The rotating wheel assembly (2) includes an annular housing (2.1), a central column (2.5) located at the axis of the annular housing (2.1), a plurality of partitions (2.2) that are radially fixedly connected between the inner peripheral wall of the annular housing (2.1) and the outer peripheral wall of the central column (2.5) and divide the inner cavity of the annular housing (2.1) into a pair of fan-shaped cavities, and zeolite units (2.3) located between two adjacent partitions (2.2). The annular groove (2.1.1) and the annular wheel groove (2.1.3) are respectively located on the outer peripheral wall of the annular housing (2.1), and the central shaft (2.4) is fitted at the axis of the central column (2.5).
4. The horizontal zeolite rotor device according to claim 1, characterized in that: The housing (1) has a side slot (1.7) in the middle of one side wall. The driving component (3) includes a housing (5.1) fixed to the outer side wall of the housing (1) and corresponding to the side slot (1.7), a drive gear (5.2) rotatably installed in the housing (5.1) and meshing with the external gear ring (2.1.2) through the side slot (1.7), and a motor (5.3) fixed to the front wall of the housing (5.1) and used to drive the drive gear (5.2) to rotate.
5. A horizontal zeolite rotor device according to claim 2, characterized in that: Diagonal bracing rods (1.4) are fixedly connected radially between the two sides of the bottom center of the crossbeam (1.2) and the inner peripheral wall of the circular opening (1.1).
6. A horizontal zeolite rotor device according to claim 3, characterized in that: The annular shell (2.1), partition (2.2), central shaft (2.4), and central column (2.5) are all made of stainless steel.
7. A horizontal zeolite rotor device according to claim 3, characterized in that: The inner walls of the box (1) are respectively fixed with rings (1.3) that are rotatably fitted and matched with the annular shell (2.1) at the positions corresponding to the circular opening (1.1).