A plant simulation experiment device

By introducing a moisture-absorbing mechanism and a cleaning mechanism into the simulation experimental device, and using a desiccant to treat humid air, the problem of inaccurate air supply in humid environments was solved, thus improving the accuracy and convenience of the experiment.

CN224462520UActive Publication Date: 2026-07-07CHINA RAILWAY CONSTR ENG GRP INSTALLATION ENGI +1

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
CHINA RAILWAY CONSTR ENG GRP INSTALLATION ENGI
Filing Date
2025-07-01
Publication Date
2026-07-07

AI Technical Summary

Technical Problem

When existing simulation experimental devices supply air into the workshop in a humid environment, the humidity of the air causes inaccurate experimental simulations, reducing the accuracy and convenience of the simulation experiments.

Method used

A workshop simulation experimental device was designed, which includes a moisture absorption mechanism. It uses desiccant particles to absorb humid air, and the moisture absorption mechanism and cleaning mechanism ensure that the air supply is dry, thereby improving the accuracy of the experiment.

Benefits of technology

By using desiccants to treat humid air, the supply air is kept dry, which improves the accuracy and convenience of the simulation experiment and reduces the impact of humidity on the experiment.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model discloses a workshop simulation experiment device, including a main body of the simulation experiment device, which includes a simulated workshop. A simulation experiment air supply device is fixedly installed on the upper surface of the simulated workshop, and a flow equalization pipe is fixed at the end of the simulation experiment air supply device on one side of the upper surface of the simulated workshop. By designing a moisture absorption mechanism, the rear box can be fixedly installed at the tail end of the simulation experiment air supply device, and half of the desiccant particles are stored inside the storage tank. When the simulation experiment is conducted by the operation of the simulation experiment air supply device, the air entering from the tail end enters the storage tank through the rear perforated cover plate. When passing through the storage tank, the air is dried by the desiccant particles stored inside, so that the humid air entering is dried before re-entering for the air supply experiment simulation. The simulation experiment is less prone to moisture, and the experimental results are more accurate.
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Description

Technical Field

[0001] This utility model belongs to the technical field of simulation experimental devices, specifically relating to a workshop simulation experimental device. Background Technology

[0002] A workshop is a unit within an enterprise that completes certain processes or produces certain products during the production process. Cleanrooms require CFD simulation experiments during production to achieve efficient air purification and ensure the high cleanliness of the cleanroom. The existing simulation experiment equipment is used by the workshop to conduct simulation experiments before production. By using CFD thermal environment simulation to determine the air supply scheme, energy consumption is reduced, and energy saving is achieved.

[0003] Existing simulation experimental devices for workshop CFD simulation experiments use a top-mounted simulation experimental air supply device to supply air into the workshop for simulation. This air supply device draws in outside air directly through an air inlet at the rear. If the experiment is conducted in a humid environment, the incoming air will be damp, and the supplied air will also be damp inside the workshop. This dampness can easily lead to inaccurate simulation results, reduce the simulation effectiveness, and affect the ease of moisture absorption and accuracy of the simulation during workshop operation. Therefore, this utility model proposes a workshop simulation experimental device. Utility Model Content

[0004] The purpose of this utility model is to provide a workshop simulation experiment device to solve the problem mentioned in the background art that when the simulation experiment device is in a humid location for the experiment, the air entering the device is humid, and the air supplied into the workshop is also humid. When the air supplied is humid, it can easily cause inaccurate experimental simulation and reduce the experimental simulation effect.

[0005] To achieve the above objectives, this utility model provides the following technical solution: a workshop simulation experiment device, comprising a main body of the simulation experiment device, the main body of the simulation experiment device including a simulated workshop, a simulation experiment air supply device fixedly installed on the upper surface of the simulated workshop, a flow equalization pipe fixed at the end of the simulation experiment air supply device on one side of the upper surface of the simulated workshop, an airflow channel provided at the inner edge of the simulated workshop, and the flow equalization pipe communicating with the interior of the airflow channel, the main body of the simulation experiment device further comprising:

[0006] A moisture-absorbing mechanism, comprising an installation component disposed at the tail end of a simulated experimental air supply device, wherein the installation component is provided with a partitioned storage component inside, and a protective component is disposed at the tail end of the installation component;

[0007] A cleaning mechanism, comprising a cleaning component disposed at one end of the surface of a protective component, wherein a sliding connection component is provided at the end of the cleaning component, and a dust extraction component is provided at the inner bottom end of the sliding connection component.

[0008] Preferably, the mounting assembly includes a rear box that is fixedly mounted to the tail end of the simulated experimental air supply device by screws, and an air inlet mesh is integrally provided on the inner surface of the rear box, the interior of which is connected to the interior of the simulated experimental air supply device.

[0009] Preferably, the partitioned storage assembly includes an integrally formed perforated partition equidistantly located inside the rear box body, and the interior of the rear box body is divided into four storage slots by the perforated partition.

[0010] Preferably, the protective component includes a rear hole-shaped cover plate fixedly installed at the rear end of the rear box body by screws, and the rear hole-shaped cover plate matches the internal rear end structure of the rear box body, and the surface of the rear hole-shaped cover plate is in contact with the surface of the hole-shaped partition plate.

[0011] Preferably, the cleaning assembly includes a cleaning brush disposed on the surface of the rear hole-shaped cover plate, a handle integrally disposed at the middle position of the cleaning brush, a locking bolt threadedly connected to the surface of the handle, and the end of the locking bolt being embedded in the internal threaded hole of the surface of the rear hole-shaped cover plate.

[0012] Preferably, the sliding connection assembly includes grooves formed on both sides of the rear hole-shaped cover plate, a slider sliding inside the groove, and the end of the slider being fixed to the end of the cleaning brush by screws.

[0013] Preferably, the dust extraction and discharge assembly includes a dust extraction channel formed on the rear surface of the rear hole-type cover plate with the bottom end located on one side of the slide groove, and a material guide plate is fixed to the inner bottom end of the cleaning brush by screws, and the end surface of the material guide plate is in contact with the end surface of the dust extraction channel.

[0014] Compared with the prior art, the beneficial effects of this utility model are:

[0015] By designing a moisture-absorbing mechanism, the rear box can be fixedly installed at the tail end of the simulated experimental air supply device. Inside the storage tank, half of the desiccant granules are stored separately. When the simulated experimental air supply device is running, the air entering from the tail end passes through the rear perforated cover plate into the storage tank. As it passes through the storage tank, it is dried by the desiccant granules stored inside. This ensures that the incoming humid air is dried before it re-enters for the air supply experiment simulation. This reduces the likelihood of moisture in the simulation experiment, resulting in more accurate experimental results. It also improves the convenience of moisture absorption and the accuracy of the simulation when the main body of the simulated experimental device is operating inside the simulated workshop. Attached Figure Description

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

[0017] Figure 2 This is a partial cross-sectional view of the simulation experiment air supply device and the rear box of this utility model.

[0018] Figure 3 This utility model Figure 2 Enlarged structural diagram of section A;

[0019] Figure 4 This is a schematic diagram of the rear box body, rear hole-shaped cover plate, and cleaning brush structure of this utility model;

[0020] Figure 5 This utility model Figure 4 Enlarged structural diagram of section B;

[0021] In the diagram: 100, Main body of the simulation experimental device; 101, Simulated workshop; 102, Simulated experimental air supply device; 1021, Rear box; 1022, Perforated partition; 1023, Rear perforated cover; 1024, Storage tank; 1025, Air inlet mesh plate; 103, Flow equalization pipe; 104, Airflow channel; 105, Cleaning brush; 1051, Slider; 1052, Slide groove; 1053, Dust extraction channel; 1054, Material guide plate; 1055, Handle; 1056, Locking bolt. Detailed Implementation

[0022] 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.

[0023] Please see Figures 1 to 5 This utility model provides a technical solution: a workshop simulation experiment device, including a main body 100, a simulated workshop 101, a simulated air supply device 102 fixedly installed on the upper surface of the simulated workshop 101, a flow equalization pipe 103 fixedly installed at the end of the simulated air supply device 102 on one side of the upper surface of the simulated workshop 101, an airflow channel 104 provided at the inner edge of the simulated workshop 101, and the flow equalization pipe 103 communicating with the interior of the airflow channel 104; the main body 100 of the simulation experiment device is also provided with:

[0024] The moisture absorption mechanism includes an installation component located at the tail end of the simulation experiment air supply device 102. The installation component has a partition storage component inside and a protective component at the tail end of the installation component. This facilitates the moisture absorption treatment of the tail end of the simulation experiment air supply device 102 by the moisture absorption mechanism during the simulation experiment, preventing moisture from entering and effectively simulating the experiment.

[0025] To facilitate the installation and storage of desiccant granules using the mounting assembly, in this embodiment, preferably, the mounting assembly includes a rear box 1021 fixedly mounted to the tail end of the simulated experimental air supply device 102 by screws. An air inlet mesh 1025 is integrally provided on the inner surface of the rear box 1021. The interior of the air inlet mesh 1025 is connected to the interior of the simulated experimental air supply device 102. The rear box 1021 can be installed at the tail end of the simulated experimental air supply device 102 for storage and use, and when air is introduced into the interior of the rear box 1021, it enters the interior of the simulated experimental air supply device 102 through the air inlet mesh 1025.

[0026] To facilitate uniform moisture absorption during air intake and improve the moisture absorption effect through the partitioned storage component, in this embodiment, preferably, the partitioned storage component includes an integrally formed perforated partition 1022 equidistantly formed inside the rear box 1021. The interior of the rear box 1021 is divided into four storage slots 1024 by the perforated partition 1022. Half of the desiccant particles can be stored inside the storage slots 1024, and moisture absorption is achieved through the desiccant particles during air intake. This prevents moisture from entering during experimental simulations and ensures accurate experimentation.

[0027] In order to facilitate the protection of the rear end of the rear box 1021 and allow air to enter through the protective component, in this embodiment, preferably, the protective component includes a rear hole-shaped cover plate 1023 that is fixedly installed at the rear end of the rear box 1021 by screws, and the rear hole-shaped cover plate 1023 matches the internal rear end structure of the rear box 1021. The surface of the rear hole-shaped cover plate 1023 is in contact with the surface of the hole-shaped partition plate 1022, so that the rear hole-shaped cover plate 1023 can be fixedly installed at the rear end of the rear box 1021 for fixed protection and effective air entry.

[0028] The cleaning mechanism includes a cleaning component disposed at one end of the surface of the protective component, a sliding connection component at the end of the cleaning component, and a dust discharge component disposed at the inner bottom end of the sliding connection component. When dust adheres to the surface of the rear hole cover 1023 during the simulation experiment, the cleaning mechanism can clean the surface of the rear hole cover 1023 without affecting the air intake simulation experiment.

[0029] To facilitate the cleaning of dust that has accumulated on the surface of the rear hole cover 1023 over a long period of time without affecting air intake, in this embodiment, preferably, the cleaning component includes a cleaning brush 105 disposed on the surface of the rear hole cover 1023. A handle 1055 is integrally provided at the middle position of the cleaning brush 105, and a locking bolt 1056 is threadedly connected to the surface of the handle 1055. The end of the locking bolt 1056 is embedded in the internal threaded hole on the surface of the rear hole cover 1023. During cleaning, the handle 1055 can be held to slide the cleaning brush 105 for cleaning. When not cleaning, the locking bolt 1056 can be rotated to fix the handle 1055, thereby fixing the cleaning brush 105 in place.

[0030] In order to facilitate the sliding adjustment and cleaning of the cleaning brush 105 by means of the sliding connection assembly, in this embodiment, preferably, the sliding connection assembly includes a sliding groove 1052 formed on both sides of the rear hole-shaped cover plate 1023, and a slider 1051 sliding inside the sliding groove 1052. The end of the slider 1051 is fixed to the end of the cleaning brush 105 by screws. The cleaning brush 105 is brought into contact with the surface of the rear hole-shaped cover plate 1023 for sliding cleaning by the slider 1051 sliding inside the sliding groove 1052.

[0031] In order to facilitate the falling and removal of dust after cleaning by the dust extraction component, in this embodiment, preferably, the dust extraction component includes a dust extraction channel 1053 opened on the rear surface of the rear hole-type cover plate 1023 with the bottom end located on one side of the slide groove 1052. The bottom inner side of the cleaning brush 105 is fixed with a material guide plate 1054 by screws. The end surface of the material guide plate 1054 is in contact with the end surface of the dust extraction channel 1053. The dust after cleaning by the cleaning brush 105 falls to the bottom and is introduced into the interior of the dust extraction channel 1053 through the material guide plate 1054, and then discharged to the outside through the dust extraction channel 1053.

[0032] The working principle and usage process of this utility model are as follows: When conducting experiments, the simulation experiment air supply device 102 is directly fixedly installed at the top of the simulation workshop 101. The simulation experiment air supply device 102 is operated to allow air to enter the interior of the flow equalization pipe 103, and then enter the interior of the airflow channel 104 through the flow equalization pipe 103 to conduct an air intake simulation experiment on the intake environment. This achieves high-efficiency air circulation and purification treatment. Based on the CFD simulation results, energy consumption is reduced, and the goal of energy saving is achieved.

[0033] Then, before the experiment, the main body 100 of the simulation experiment device is installed with the rear box 1021 fixedly at the tail end of the simulation experiment air supply device 102, and half of the desiccant particles are evenly injected into the storage tank 1024. The rear hole cover 1023 is closed again to fix and store it. When the simulation experiment air supply device 102 is operated, when the air enters through the tail end of the simulation experiment air supply device 102, the air enters through the rear hole cover 1023 into the storage tank 1024. When passing through the storage tank 1024, it is dried by the desiccant particles stored inside, so that the humid air that enters is dried and then enters again for air supply experiment simulation. It is not easy for moisture to occur during the simulation experiment, the experimental results are more accurate, and the convenience of moisture absorption and the accuracy of simulation are improved when the main body 100 of the simulation experiment device is operated in the simulation workshop 101.

[0034] Finally, after prolonged experimental processing, when dust appears and adheres to the surface of the rear hole cover plate 1023, the rear hole cover plate 1023 is opened, the locking bolt 1056 is loosened, and the handle 1055 is held and slids inside the slide groove 1052 via the slider 1051 to drive the cleaning brush 105 to slide and clean the surface of the rear hole cover plate 1023. When the dust generated during the sliding cleaning process falls to the bottom, it is guided by the material guide plate 1054 to the inside of the dust collection channel 1053, and then the dust is discharged to the outside through the dust collection channel 1053. This facilitates the cleaning process and simulates air intake for the experiment, improving the convenience of cleaning the surface of the rear hole cover plate 1023 during the workshop simulation experiment of the main body 100 of the simulation experiment device, and effectively simulating air intake experimental processing.

[0035] Although embodiments of the present invention have been shown and described (see the detailed description above), 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 workshop simulation experiment device, comprising a main body (100) of the simulation experiment device, the main body (100) comprising a simulation workshop (101), a simulation experiment air supply device (102) fixedly installed on the upper surface of the simulation workshop (101), a flow equalization pipe (103) fixedly located at the end of the simulation experiment air supply device (102) on one side of the upper surface of the simulation workshop (101), an airflow channel (104) provided at the inner edge of the simulation workshop (101), and the flow equalization pipe (103) communicating with the interior of the airflow channel (104), characterized in that: The main body (100) of the simulation experimental device is also equipped with: A moisture-absorbing mechanism, and the moisture-absorbing mechanism includes an installation component disposed at the tail end of the simulated experimental air supply device (102), wherein the installation component is provided with a partition storage component inside, and a protective component is disposed at the tail end of the installation component; A cleaning mechanism, comprising a cleaning component disposed at one end of the surface of a protective component, wherein a sliding connection component is provided at the end of the cleaning component, and a dust extraction component is provided at the inner bottom end of the sliding connection component.

2. The workshop simulation experimental device according to claim 1, characterized in that: The mounting assembly includes a rear box (1021) that is fixedly mounted to the tail end of the simulation experiment air supply device (102) by screws. An air inlet mesh plate (1025) is integrally provided on the inner surface of the rear box (1021), and the interior of the air inlet mesh plate (1025) is connected to the interior of the simulation experiment air supply device (102).

3. The workshop simulation experimental device according to claim 2, characterized in that: The partitioned storage assembly includes an integrally formed perforated partition (1022) equidistantly formed inside the rear housing (1021), and the interior of the rear housing (1021) is divided by the perforated partition (1022) to form four storage slots (1024).

4. The workshop simulation experimental device according to claim 2, characterized in that: The protective assembly includes a rear hole-type cover plate (1023) fixedly installed at the rear end of the rear box (1021) by screws, and the rear hole-type cover plate (1023) matches the internal rear end structure of the rear box (1021), and the surface of the rear hole-type cover plate (1023) is in contact with the surface of the hole-type partition plate (1022).

5. The workshop simulation experimental device according to claim 4, characterized in that: The cleaning assembly includes a cleaning brush (105) disposed on the surface of a rear hole-type cover plate (1023). A handle (1055) is integrally disposed at the middle position of the cleaning brush (105). A locking bolt (1056) is threadedly connected to the surface of the handle (1055). The end of the locking bolt (1056) is embedded in an internal threaded hole on the surface of the rear hole-type cover plate (1023).

6. The workshop simulation experimental device according to claim 5, characterized in that: The sliding connection assembly includes a slide groove (1052) on both sides of the rear hole-type cover plate (1023), and a slider (1051) slides inside the slide groove (1052). The end of the slider (1051) is fixed to the end of the cleaning brush (105) by screws.

7. The workshop simulation experimental device according to claim 6, characterized in that: The dust extraction assembly includes a dust extraction channel (1053) with the bottom end of the rear surface of the rear hole-type cover plate (1023) located on one side of the slide groove (1052). The bottom inner side of the cleaning brush (105) is fixed with a material guide plate (1054) by screws. The end surface of the material guide plate (1054) is in contact with the end surface of the dust extraction channel (1053).