A baffle-type gas adsorption column
By designing diversion and sliding components in the baffled gas adsorption tower, the gas flow direction is changed and the activated carbon components are easily replaced, thus solving the problem of uneven utilization of activated carbon and improving resource utilization and safety.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SUZHOU DINGYU ENERGY CONSERVATION & ENVIRONMENTAL PROTECTION CO LTD
- Filing Date
- 2025-07-28
- Publication Date
- 2026-07-07
Smart Images

Figure CN224462504U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of gas adsorption technology, and specifically relates to a baffled gas adsorption tower. Background Technology
[0002] An adsorption tower is a device that uses an adsorbent to selectively adsorb specific components in a gas or liquid, thereby achieving the separation, purification, or refining of mixtures. It has wide applications in many fields such as chemical engineering, environmental protection, and food. A baffle-type gas adsorption tower changes the direction of gas flow by installing baffles inside the adsorption tower, which also increases the contact area between the gas and activated carbon and prolongs the time the gas spends inside the adsorption tower, thus ensuring that the adsorption tower fully absorbs harmful substances in the gas.
[0003] According to a baffle-type gas adsorption tower disclosed in Chinese Patent Publication No. CN222489497U, the gas enters the main shell through the inlet pipe and passes through the treatment box through the through hole. The gas is adsorbed by the activated carbon filling in the treatment box. The baffle, the first opening groove and the second opening groove are set to prolong the flow of gas in the treatment box, so that the gas is more fully adsorbed. When the activated carbon filling needs to be replaced, the moving frame drives the treatment box to move and adjust under the action of the motor, bevel gear set and lead screw, so that the treatment box is partially moved out of the main shell, and the sealing plate is slid out through the slide groove to facilitate the cleaning out of the activated carbon filling in the treatment box.
[0004] Because the harmful gases in the exhaust gas first come into contact with the activated carbon on the inlet side of the exhaust pipe, and then pass through the through hole to come into contact with the activated carbon on the outlet side, the concentration of harmful gases adsorbed by the activated carbon in the two parts is different. As a result, the activated carbon on the outlet side cannot be fully utilized, which leads to a waste of resources. If the cleaning time is delayed, the harmful gases are likely to flow out from the outlet pipe, which will lead to air pollution. Utility Model Content
[0005] To address the problem that harmful gases in exhaust gas first come into contact with the activated carbon on the inlet side of the exhaust pipe and then pass through the through-hole to contact the activated carbon on the outlet side, resulting in different concentrations of harmful gases adsorbed by the activated carbon on the two sides, the activated carbon on the outlet side cannot be fully utilized, leading to resource waste. If the cleaning time is delayed, harmful gases are likely to flow out of the outlet pipe, causing air pollution. This utility model proposes a baffle-type gas adsorption tower to overcome the above-mentioned technical problems existing in the existing related technologies.
[0006] To solve the above-mentioned technical problems, this utility model is achieved through the following technical solution:
[0007] This utility model relates to a baffled gas adsorption tower, comprising a shell, a flow-dividing component fixedly connected inside the shell, an adsorption component disposed inside the shell, a first sliding component fixedly installed at the bottom end of the adsorption component, the bottom end of the first sliding component being fixedly installed inside the shell, a second sliding component disposed inside the adsorption component, snap-fit components disposed inside both the shell and the adsorption component, and sealing components disposed inside both the shell and the adsorption component, an air inlet being provided on one side of the shell, and an air outlet being provided on the other side of the shell.
[0008] Furthermore, the flow diversion assembly includes a fixed base and a baffle plate. The outer surface of the fixed base is fixedly connected to the interior of the housing. A filter screen is fixedly installed on one side of the fixed base. The outer surface of the baffle plate is fixedly connected to the interior of the housing.
[0009] Furthermore, the adsorption assembly includes a guide hole disposed inside the housing, and an adsorption box is slidably connected inside the guide hole, with a through hole opened inside the adsorption box.
[0010] Furthermore, the first sliding component includes a slider, the top end of which is fixedly installed with the bottom end of the adsorption box, and a slide rail is slidably connected inside the slider, the bottom end of which is fixedly installed with the inside of the housing.
[0011] Furthermore, the second sliding component includes a first sliding groove, which is formed inside the adsorption box. A sliding plate is slidably connected inside the first sliding groove. A handle is fixedly installed on one side of the sliding plate, and a first connecting rod is fixedly connected to the other side of the sliding plate. A second connecting rod is fixedly connected to both ends of the first connecting rod, and a wedge is fixedly installed at both ends of the second connecting rod.
[0012] Furthermore, the snap-fit assembly includes a fixing groove and a snap-fit slot. The fixing groove is formed inside the housing, and a second sliding groove is formed inside the fixing groove. A sliding rod is slidably connected inside the second sliding groove. A snap-fit block is fixedly connected to one end of the sliding rod. A spring is fixedly installed inside the snap-fit block, and one end of the spring is fixedly installed inside the fixing groove. A push rod is fixedly connected to one side of the snap-fit block. The snap-fit slot is formed on the outer surface of the adsorption box, and the outer surface of the snap-fit block snaps into the inside of the snap-fit slot.
[0013] Furthermore, the sealing assembly includes a sealing groove and a circular groove. The sealing groove is formed on the outer surface of the housing, and the circular groove is formed on the outer surface of the adsorption box. A rubber ring is fixedly installed inside the circular groove, and the outer surface of the rubber ring is interference-fitted with the inner wall of the sealing groove.
[0014] This utility model has the following beneficial effects:
[0015] 1. This utility model connects an external fan to the air inlet, allowing the external fan to blow the mixed gas into the interior of the housing from the air inlet. Since the diversion component is fixedly installed inside the housing, when the mixed gas enters the housing, it contacts the diversion component, thus directing the flow of the mixed gas and diverting it. This prolongs the time the mixed gas spends inside the housing, allowing it to fully contact the activated carbon inside the adsorption component. The activated carbon then adsorbs harmful gases in the mixed gas. After adsorption, the gas is discharged through the air outlet. After adsorption, the second sliding component is pushed upwards. Since the locking component is located above the second sliding component, when the second sliding component... When the moving component moves upward, it pushes the locking component at the top to move outward and release the locking state. At the same time, it pulls the second sliding component outward from the housing, causing the second sliding component to move the adsorption component slidably connected to the outer surface outward from the housing. This causes the adsorption component to slide outward from the bottom fixed first sliding component, making it easier for the adsorption component to exit the housing. This allows workers to check the adsorption status of the activated carbon inside multiple adsorption components, replace adsorption components that can no longer adsorb harmful gases, and move adsorption components that can continue to adsorb harmful gases closer to the air inlet. This ensures that the activated carbon inside the adsorption component is fully utilized, improving resource utilization.
[0016] Of course, any product implementing this utility model does not necessarily need to achieve all of the advantages described above at the same time. Attached Figure Description
[0017] To more clearly illustrate the technical solutions of the utility model embodiments, the accompanying drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of the utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0018] Figure 1 This is a three-dimensional structural diagram of the present invention;
[0019] Figure 2 This is a schematic diagram of the cross-sectional structure of the present invention from a rear-view perspective;
[0020] Figure 3 This is a schematic diagram of the structure of this utility model from a right-side view.
[0021] Figure 4 This is a schematic diagram of the cross-sectional structure of the present invention from a frontal view.
[0022] Figure 5 This is a schematic diagram of the internal structure of the shell of this utility model;
[0023] Figure 6This is a schematic diagram of the internal structure of the snap-fit assembly of this utility model;
[0024] Figure 7 For the present utility model Figure 4 Enlarged view of a portion of point A in the middle;
[0025] Figure 8 For the present utility model Figure 6 A magnified view of a portion of point B in the middle.
[0026] The attached diagram lists the components represented by each number as follows:
[0027] 1. Housing; 2. Diverter assembly; 201. Fixing base; 202. Baffle plate; 203. Filter screen; 3. Adsorption assembly; 301. Guide hole; 302. Adsorption box; 303. Through hole; 4. First sliding assembly; 401. Slider; 402. Slide rail; 5. Second sliding assembly; 501. First slide groove; 502. Slide plate; 503. Handle; 504. First connecting rod; 505. Second connecting rod; 506. Wedge block; 6. Snap-fit assembly; 601. Fixing groove; 602. Snap groove; 603. Second slide groove; 604. Slide rod; 605. Snap block; 606. Spring; 607. Push rod; 7. Sealing assembly; 701. Sealing groove; 702. Circular groove; 703. Rubber ring; 8. Air inlet; 9. Air outlet. Detailed Implementation
[0028] The technical solutions of the utility model embodiments will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the utility model, and not all embodiments. Based on the embodiments of the utility model, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the utility model.
[0029] In the description of this utility model, it should be understood that the terms "opening", "upper", "lower", "top", "middle", "inner", etc., which indicate orientation or positional relationship, are only for the convenience of describing the utility model and simplifying the description, and do not indicate or imply that the components or elements referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on the utility model.
[0030] Please see Figures 1-8As shown, this utility model is a baffled gas adsorption tower, including a shell 1. A diversion component 2 is fixedly connected inside the shell 1. An adsorption component 3 is disposed inside the shell 1. A first sliding component 4 is fixedly installed at the bottom end of the adsorption component 3. The bottom end of the first sliding component 4 is fixedly installed inside the shell 1. A second sliding component 5 is disposed inside the adsorption component 3. A snap-fit component 6 is disposed inside both the shell 1 and the adsorption component 3. A sealing component 7 is disposed inside both the shell 1 and the adsorption component 3. An air inlet 8 is opened on one side of the shell 1, and an air outlet 9 is opened on the other side of the shell 1.
[0031] By adding activated carbon inside the adsorption component 3 and then pushing the adsorption component 3 into the housing 1, the adsorption component 3 causes the first sliding component 4, which is fixedly installed at the bottom, to slide, thus facilitating the adsorption component 3 to enter the interior of the housing 1. Simultaneously, as the adsorption component 3 moves, it causes the internally installed snap-fit component 6 to move as well. Since the aperture of the opening inside the housing 1 is larger than the outer diameter of the adsorption component 3, the housing 1 can enclose the adsorption component 3, allowing the snap-fit component 6 inside the housing 1 to enter and secure the adsorption component 3. Simultaneously, as the adsorption component 3 moves, it causes the internally installed sealing component 7 to move, allowing the sealing component 7 inside the adsorption component 3 to enter the interior of the housing 1, so that the outer surface of the sealing component 7 is press-fitted with the exterior of the housing 1, thus achieving a seal. Then, an external fan is connected to the air inlet 8, allowing the external fan to blow the mixed gas into the interior of the housing 1 from the air inlet 8. Since the diversion component 2 is fixedly installed inside the housing, when the mixed gas enters the interior of the housing 1, it will contact the diversion component 2, thus... The diversion component 2 changes the flow direction of the mixed gas and diverts it, thereby extending the time the mixed gas spends inside the housing 1. This allows the mixed gas to fully contact the activated carbon inside the adsorption component 3, enabling the activated carbon to adsorb harmful gases in the mixed gas. The adsorbed gas is then discharged through the air outlet 9. After adsorption is complete, the second sliding component 5 is pushed upward. Since the locking component 6 is located above the second sliding component 5, when the second sliding component 5 moves upward, it pushes the locking component 6 at the top to move outward and release the locking state. At the same time, it pulls the second sliding component 5 outward from the housing 1, causing the second sliding component 5 to move the adsorption component 3, which is slidably connected to the outer surface, outward. This causes the adsorption component 3 to slide outward along with the first sliding component 4, which is fixed at the bottom. This facilitates the adsorption component 3 to exit the housing 1, allowing workers to check the adsorption status of the activated carbon inside multiple adsorption components 3 and replace adsorption components 3 that can no longer adsorb harmful gases. Adsorption components 3 that can continue to adsorb harmful gases are then moved closer to the air inlet 8, ensuring that the activated carbon inside the adsorption component 3 is fully utilized and improving resource utilization.
[0032] An external fan is connected to the air inlet 8, allowing the external fan to blow the mixed gas into the interior of the housing 1 from the air inlet 8. Since the diversion component 2 is fixedly installed inside the housing, when the mixed gas enters the housing 1, it contacts the diversion component 2, causing the diversion component 2 to change the flow direction of the mixed gas and divert it, thus prolonging the time the mixed gas spends inside the housing 1. This allows the mixed gas to fully contact the activated carbon inside the adsorption component 3, enabling the activated carbon to adsorb harmful gases in the mixed gas. After adsorption, the gas is discharged through the air outlet 9. After adsorption, the second sliding component 5 is pushed upwards. Since the locking component 6 is located above the second sliding component 5, when the second sliding component 5 moves upwards... When moving upwards, it can push the locking component 6 at the top to move outwards and release the locking state. At the same time, it pulls the second sliding component 5 outwards from the housing 1, causing the second sliding component 5 to drive the adsorption component 3, which is slidably connected to the outer surface, to move outwards from the housing. This causes the adsorption component 3 to drive the first sliding component 4, which is fixedly installed at the bottom, to slide outwards, thus facilitating the adsorption component 3 to exit the housing 1. This makes it easier for workers to check the adsorption status of the activated carbon inside the multiple adsorption components 3, and to replace the adsorption components 3 that can no longer adsorb harmful gases. The adsorption components 3 that can continue to adsorb harmful gases are replaced to a position closer to the air inlet 8, thereby making full use of the activated carbon inside the adsorption component 3 and improving resource utilization.
[0033] In one embodiment, the diversion component 2 includes a fixed base 201 and a baffle plate 202. The outer surface of the fixed base 201 is fixedly connected to the interior of the housing 1. A filter screen 203 is fixedly installed on one side of the fixed base 201. The outer surface of the baffle plate 202 is fixedly connected to the interior of the housing 1.
[0034] When the mixed gas enters the housing 1 through the air inlet 8, the mixed gas flows into the housing 1, passing through the fixed base 201 fixedly connected inside the housing 1, and through the filter screen 203 fixedly installed on one side of the fixed base 201. The filter screen 203 filters the mixed gas, separating the particulate matter inside the mixed gas from the gas. The filtered mixed gas continues to flow into the housing 1, thereby contacting the baffle plate 202 fixedly connected inside the housing 1. The baffle plate 202 changes the flow direction of the mixed gas, thereby prolonging the residence time of the mixed gas inside the housing 1.
[0035] In one embodiment, the adsorption component 3 includes a guide hole 301, which is disposed inside the housing 1. An adsorption box 302 is slidably connected inside the guide hole 301, and a through hole 303 is provided inside the adsorption box 302.
[0036] When the filtered mixed gas enters the housing 1, it enters the adsorption box 302 through the through holes 303 inside the adsorption box 302, so that the mixed gas comes into contact with the activated carbon inside the adsorption box 302, and the activated carbon adsorbs the harmful gases in the mixed gas. Since there are multiple sets of through holes 303 arranged in an array, the mixed gas can be dispersed into the adsorption box 302, thereby improving the adsorption efficiency of harmful gases.
[0037] In one embodiment, the first sliding component 4 includes a slider 401, the top end of which is fixedly installed with the bottom end of the adsorption box 302, and a slide rail 402 is slidably connected inside the slider 401, the bottom end of which is fixedly installed with the inside of the housing 1.
[0038] By pushing the adsorption box 302 into the housing 1, the adsorption box 302 drives the slider 401, which is fixedly installed at the bottom, to move into the housing 1. Since the bottom of the slide rail 402 is fixedly installed in the housing 1, the slider 401 can slide on the surface of the slide rail 402 into the housing 1, thereby reducing the friction between the adsorption box 302 and the housing 1, and making it easier for the adsorption box 302 to enter and exit the housing 1.
[0039] In one embodiment, the second sliding component 5 includes a first sliding groove 501, which is formed inside the adsorption box 302. A sliding plate 502 is slidably connected inside the first sliding groove 501. A handle 503 is fixedly installed on one side of the sliding plate 502, and a first connecting rod 504 is fixedly connected to the other side of the sliding plate 502. A second connecting rod 505 is fixedly connected to both ends of the first connecting rod 504, and a wedge 506 is fixedly installed at both ends of the second connecting rod 505.
[0040] By pushing the handle 503 upwards, the slide plate 502, which is fixedly installed on one side, moves upwards, causing the slide plate 502 to slide upwards inside the first slide groove 501. This causes the slide plate 502 to move the first connecting rod 504, which is fixedly connected on one side, upwards. In turn, the first connecting rod 504 moves the second connecting rod 505, which is fixedly connected at both ends, upwards. This causes the second connecting rod 505 to move the wedges 506, which are fixedly installed at both ends, upwards. As a result, the slide plate 502, the first connecting rod 504, the second connecting rod 505, and the wedges 506 slide upwards inside the first slide groove 501. This allows the first slide groove 501 to restrict the direction of movement of the slide plate 502, the first connecting rod 504, the second connecting rod 505, and the wedges 506, thereby improving the stability of the slide plate 502, the first connecting rod 504, and the second connecting rod 505 during movement.
[0041] In one embodiment, the snap-fit assembly 6 includes a fixing groove 601 and a snap-fit slot 602. The fixing groove 601 is located inside the housing 1. A second sliding groove 603 is provided inside the fixing groove 601. A sliding rod 604 is slidably connected inside the second sliding groove 603. A snap-fit block 605 is fixedly connected to one end of the sliding rod 604. A spring 606 is fixedly installed inside the snap-fit block 605. One end of the spring 606 is fixedly installed inside the fixing groove 601. A push rod 607 is fixedly connected to one side of the snap-fit block 605. The snap-fit slot 602 is located on the outer surface of the adsorption box 302. The outer surface of the snap-fit block 605 snaps into the interior of the snap-fit slot 602.
[0042] When the wedge 506 moves upward, since the top of the wedge 506 is set as an upward inclined surface and the wedge 506 is located below the push rod 607, when the wedge 506 moves upward, it can push the push rod 607 to move outward. This causes the push rod 607 to drive the locking block 605, which is fixedly connected at one end, to move outward. This causes the locking block 605 to compress the spring 606 fixedly installed inside, so that the locking block 605 moves away from the slot 602 opened on the outer surface of the adsorption box 302. This releases the locking block 605 from the slot 602. Since there are multiple sets of retaining groove 601, slot 602, second sliding groove 603, sliding rod 604, locking block 605, spring 606 and push rod 607, and they are arranged symmetrically, the stability of the connection between the adsorption box 302 and the shell 1 can be guaranteed, and the mixed gas inside the shell 1 can be prevented from pushing the adsorption box 302 out.
[0043] In one embodiment, the sealing assembly 7 includes a sealing groove 701 and a circular groove 702. The sealing groove 701 is formed on the outer surface of the housing 1, and the circular groove 702 is formed on the outer surface of the adsorption box 302. A rubber ring 703 is fixedly installed inside the circular groove 702, and the outer surface of the rubber ring 703 is interference-fitted with the inner wall of the sealing groove 701.
[0044] When the adsorption box 302 moves into the housing 1, it causes the rubber ring 703 fixedly installed inside to move into the housing 1. Since the inner diameter of the rubber ring 703 is slightly smaller than the inner diameter of the sealing groove 701 opened on the outer surface of the housing 1, and the outer diameter of the rubber ring 703 is slightly larger than the outer diameter of the sealing groove 701 opened on the outer surface of the housing 1, and the rubber ring 703 has a certain elasticity, the sealing groove 701 can wrap around the outer surface of the rubber ring 703, so that the outer surface of the rubber ring 703 and the inner wall of the sealing groove 701 are interference fit, thereby achieving the purpose of sealing and preventing the mixed gas from leaking out.
[0045] In summary, by adding activated carbon into the adsorption box 302 and then pushing the adsorption box 302 into the housing 1, the adsorption box 302 causes the slider 401 fixedly installed at the bottom to slide into the housing 1, thus facilitating the entry and exit of the adsorption box 302 into the housing 1. Simultaneously, during the movement of the adsorption box 302, it contacts and pushes the locking blocks 605 to both sides, thereby compressing the internally fixed spring 606. When the adsorption box 302 moves to one side of the locking block 605 along with the locking groove 602 on its outer surface, the spring 606 releases its compressive stress and pushes the locking block 605 back to its original position, allowing the locking block 605 to enter the interior of the locking groove 602 and engage with the locking groove 602 to position the adsorption box 302. Simultaneously, during the movement of the adsorption box 302, it causes the internally fixed rubber ring 703 to move towards the housing 1. Since the inner diameter of the rubber ring 703 is slightly smaller than the sealing groove 701 on the outer surface of the housing 1... The outer diameter of the rubber ring 703 is slightly larger than the outer diameter of the sealing groove 701 opened on the outer surface of the shell 1. The rubber ring 703 has a certain elasticity, which allows the sealing groove 701 to wrap around the outer surface of the rubber ring 703, so that the outer surface of the rubber ring 703 and the inner wall of the sealing groove 701 are interference fit, thereby achieving the purpose of sealing. Then, an external fan is connected to the air inlet 8, and the external fan blows the mixed gas into the interior of the shell 1 through the air inlet 8, so that the mixed gas enters the shell 1 and is filtered by the filter screen 203 to separate the particulate matter from the mixed gas. The filtered gas enters the interior of the adsorption box 302 through the through hole 303 and comes into contact with the activated carbon, so that the activated carbon adsorbs the harmful gases in the mixed gas. The adsorbed gas flows out of the adsorption box 302 through the through hole 303 and comes into contact with the baffle plate 202, so that the baffle plate 202 changes the flow direction of the gas, thereby prolonging the residence time of the gas inside the shell 1. The adsorbed gas will be discharged through the air outlet 9.
[0046] After adsorption is complete, pushing the handle 503 upward causes the slide plate 502 to move the first connecting rod 504 upward, which in turn moves the second connecting rod 505, which is fixedly connected at both ends, upward. This, in turn, causes the second connecting rod 505 to move the wedges 506, which are fixedly installed at both ends, upward. Since the top of the wedge 506 is sloped and has a push rod 607, when the wedge 506 moves upward, it pushes the push rod 607 outward. This push rod 607 then moves the locking block 605, which is fixedly connected at one end, outward, causing the locking block 605 to move away from the slot 602 and compress the spring 606, thus causing the locking block 605 to... Release the locking state from the slot 602, and simultaneously pull the handle 503 away from the housing 1. This causes the adsorption box 302, which is slidably connected to the surface, to move away from the housing 1 via the sliding plate 502. This causes the adsorption box 302 to move the internally fixed rubber ring 703 away from the circular groove 702, thus releasing the seal between the rubber ring 703 and the circular groove 702. This allows the adsorption box 302 to exit the housing 1, making it easier for workers to replace the adsorption box 302 that can no longer absorb harmful gases, and to replace the adsorption box 302 that can continue to absorb gases with one closer to the air inlet 8. This allows the activated carbon inside the adsorption box 302 to be fully utilized, improving resource utilization.
[0047] Through the above technical solution, 1. An external fan is connected to the air inlet 8, allowing the external fan to blow the mixed gas from the air inlet 8 into the interior of the housing 1. Since the diversion component 2 is fixedly installed inside the housing, when the mixed gas enters the housing 1, it will contact the diversion component 2, thereby changing the flow direction of the mixed gas and diverting it, thus prolonging the time the mixed gas stays inside the housing 1, allowing the mixed gas to fully contact the activated carbon inside the adsorption component 3, thereby allowing the activated carbon to adsorb the harmful gases in the mixed gas. After adsorption, the gas will be discharged through the air outlet 9. After adsorption, the second sliding component 5 is pushed upward. Since the snap-fit component 6 is located above the second sliding component 5, when the second... When the sliding component 5 moves upward, it pushes the locking component 6 at the top to move outward and release the locking state. At the same time, it pulls the second sliding component 5 outward from the housing 1, causing the second sliding component 5 to drive the adsorption component 3, which is slidably connected to the outer surface, to move outward from the housing. This causes the adsorption component 3 to drive the first sliding component 4, which is fixedly installed at the bottom, to slide outward, thus facilitating the adsorption component 3 to exit the interior of the housing 1. This makes it easier for workers to check the adsorption status of the activated carbon inside the multiple adsorption components 3, and to replace the adsorption components 3 that can no longer adsorb harmful gases. The adsorption components 3 that can continue to adsorb harmful gases are replaced and placed closer to the air inlet 8, thereby making full use of the activated carbon inside the adsorption component 3 and improving resource utilization.
[0048] In the description of this specification, references to terms such as "an embodiment," "example," "specific example," etc., indicate that a specific feature, structure, material, or characteristic described in connection with that embodiment or example is included in at least one embodiment or example of the utility model. In this specification, the illustrative expressions of the above terms do not necessarily refer to the same embodiment or example. Furthermore, the specific features, structures, materials, or characteristics described may be combined in any suitable manner in one or more embodiments or examples.
[0049] The preferred embodiments of the utility model disclosed above are merely illustrative of the utility model. These preferred embodiments do not exhaustively describe all details, nor do they limit the utility model to the specific implementations described. Clearly, many modifications and variations can be made based on the content of this specification. This specification selects and specifically describes these embodiments to better explain the principles and practical applications of the utility model, thereby enabling those skilled in the art to better understand and utilize it. The utility model is limited only by the claims and their full scope and equivalents.
Claims
1. A baffled gas adsorption tower, comprising a shell (1), characterized in that, A diversion component (2) is fixedly connected inside the housing (1). An adsorption component (3) is provided inside the housing (1). A first sliding component (4) is fixedly installed at the bottom end of the adsorption component (3). The bottom end of the first sliding component (4) is fixedly installed inside the housing (1). A second sliding component (5) is provided inside the adsorption component (3). A snap-fit component (6) is provided inside both the housing (1) and the adsorption component (3). A sealing component (7) is provided inside both the housing (1) and the adsorption component (3). An air inlet (8) is opened on one side of the housing (1), and an air outlet (9) is opened on the other side of the housing (1).
2. The baffled gas adsorption tower according to claim 1, characterized in that, The diversion assembly (2) includes a fixed base (201) and a baffle plate (202). The outer surface of the fixed base (201) is fixedly connected to the inside of the housing (1). A filter screen (203) is fixedly installed on one side of the fixed base (201). The outer surface of the baffle plate (202) is fixedly connected to the inside of the housing (1).
3. A baffle-type gas adsorption tower according to claim 1, characterized in that, The adsorption assembly (3) includes a guide hole (301), which is located inside the housing (1). An adsorption box (302) is slidably connected inside the guide hole (301), and a through hole (303) is provided inside the adsorption box (302).
4. A baffle-type gas adsorption tower according to claim 3, characterized in that, The first sliding component (4) includes a slider (401), the top of which is fixedly installed with the bottom of the adsorption box (302), and a slide rail (402) is slidably connected inside the slider (401), and the bottom of the slide rail (402) is fixedly installed inside the housing (1).
5. A baffled gas adsorption tower according to claim 4, characterized in that, The second sliding component (5) includes a first slide groove (501), which is opened inside the adsorption box (302). A slide plate (502) is slidably connected inside the first slide groove (501). A handle (503) is fixedly installed on one side of the slide plate (502). A first connecting rod (504) is fixedly connected to the other side of the slide plate (502). A second connecting rod (505) is fixedly connected to both ends of the first connecting rod (504). A wedge (506) is fixedly installed at both ends of the second connecting rod (505).
6. A baffle-type gas adsorption tower according to claim 3, characterized in that, The snap-fit assembly (6) includes a fixing groove (601) and a snap-fit groove (602). The fixing groove (601) is located inside the housing (1). A second sliding groove (603) is provided inside the fixing groove (601). A sliding rod (604) is slidably connected inside the second sliding groove (603). A snap-fit block (605) is fixedly connected to one end of the sliding rod (604). A spring (606) is fixedly installed inside the snap-fit block (605). One end of the spring (606) is fixedly installed inside the fixing groove (601). A push rod (607) is fixedly connected to one side of the snap-fit block (605). The snap-fit groove (602) is located on the outer surface of the adsorption box (302). The outer surface of the snap-fit block (605) and the inside of the snap-fit groove (602) snap-fit each other.
7. A baffle-type gas adsorption tower according to claim 3, characterized in that, The sealing assembly (7) includes a sealing groove (701) and a circular groove (702). The sealing groove (701) is formed on the outer surface of the housing (1), and the circular groove (702) is formed on the outer surface of the adsorption box (302). A rubber ring (703) is fixedly installed inside the circular groove (702), and the outer surface of the rubber ring (703) is interference-fitted with the inner wall of the sealing groove (701).