An explosion-proof exhaust cabinet

By introducing an anti-static transmission unit, a synchronization unit, and a counterweight unit into the explosion-proof ventilation cabinet, and by using a buffer unit and lubricating grease, the problems of impact and friction ignition sources between moving parts are solved, thereby improving the explosion-proof safety of the equipment.

CN224463404UActive Publication Date: 2026-07-07E3 GREEN TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
E3 GREEN TECH CO LTD
Filing Date
2026-05-28
Publication Date
2026-07-07

AI Technical Summary

Technical Problem

Existing explosion-proof fume hoods neglect the risk of mechanical ignition sources such as impacts and friction between moving parts in their mechanical structure design, resulting in significant safety hazards in explosive environments.

Method used

An explosion-proof exhaust cabinet is designed by employing an anti-static transmission unit, an anti-static synchronization unit, and an anti-static counterweight unit, combined with a buffer unit and lubricating grease. This design absorbs impact energy through buffering, reduces frictional heat generation and static electricity accumulation, and avoids ignition sources generated by hard impacts and friction.

Benefits of technology

It effectively reduces the risk of ignition sources caused by impact and friction, improves the overall safety performance of explosion-proof ventilation cabinets in explosive hazardous environments, and ensures the explosion-proof reliability of the transmission system and the overall explosion-proof safety.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses an anti -explosion exhaust cabinet, include: cabinet, have working cavity, window subassembly, set up in the front wall of cabinet, window subassembly can open along the first direction to form the front opening that opens to the indoor environment, transmission subassembly, including antistatic transmission unit, antistatic synchronous unit and antistatic counterweight unit, antistatic synchronous unit is set in antistatic transmission unit, and is connected window subassembly and antistatic counterweight unit respectively, buffer unit, set up in the cabinet, along the first direction, buffer unit is located between antistatic counterweight unit and the cabinet, the utility model discloses an anti -explosion exhaust cabinet provides the buffer protection, can reduce the risk of explosion because of the impact, and the mechanical ignition source is eliminated.
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Description

Technical Field

[0001] This utility model relates to the field of fume hood technology, and in particular to an explosion-proof fume hood. Background Technology

[0002] Currently, most explosion-proof fume hoods on the market suffer from design flaws. Most products are simply ordinary fume hoods with some external electrical components (such as lights, sockets, and switches) replaced with explosion-proof models, while the main structure of the cabinet remains using non-explosion-proof materials and construction. This approach essentially only achieves localized electrical explosion protection, neglecting the requirements of the overall explosion-proof safety system. This leads to the following problems: it ignores the risks of mechanical ignition sources such as impacts and friction between moving parts, for example, using easily broken or impact-prone components like chain drives and steel springs, and relying excessively on passive measures such as grounding, resulting in significant safety hazards even in explosive environments. Utility Model Content

[0003] The purpose of this invention is to address the problem that the mechanical structure of existing explosion-proof fume hoods neglects the risk of mechanical ignition sources such as impacts and friction between moving parts. This invention provides an explosion-proof fume hood with buffer protection, reducing the risk of explosion due to impact and eliminating mechanical ignition sources.

[0004] To address the aforementioned technical problems, this utility model discloses an explosion-proof fume hood, comprising: a cabinet body having a working chamber; a viewing window assembly disposed on the front wall of the cabinet body, the viewing window assembly being openable along a first direction to form a front opening to the indoor environment; a transmission assembly including an antistatic transmission unit, an antistatic synchronization unit, and an antistatic counterweight unit, the antistatic synchronization unit being sleeved on the antistatic transmission unit and respectively connected to the viewing window assembly and the antistatic counterweight unit; and a buffer unit disposed on the cabinet body, along the first direction, the buffer unit being located above the antistatic counterweight unit, and / or, the buffer unit being located below the antistatic counterweight unit.

[0005] By adopting the above technical solution, the explosion-proof exhaust cabinet of this application embodiment can effectively absorb the impact energy when the window component moves to a preset position (such as the highest or lowest position) by setting a buffer unit between the anti-static counterweight unit and the cabinet body, thereby eliminating hard impact between the above components and systematically eliminating the ignition source from the perspective of mechanical structure, significantly improving the overall safety performance of the explosion-proof exhaust cabinet in the hazardous environment of explosion.

[0006] According to another specific embodiment of the present invention, an explosion-proof exhaust cabinet is disclosed. The antistatic synchronization unit includes: a first end connected to the window assembly; a second end bypassing the antistatic transmission unit and connected to the antistatic counterweight unit; and a middle part located between the first end and the second end. The transmission assembly further includes: lubricating grease coated on the middle part of the antistatic synchronization unit.

[0007] By adopting the above technical solution, lubricating grease can be placed between the middle part of the antistatic synchronization unit and the antistatic transmission unit, which can effectively reduce the frictional heat generation and static electricity accumulation during the relative movement of the two, and further reduce the risk of ignition source caused by friction.

[0008] According to another specific embodiment of the present invention, an explosion-proof exhaust cabinet is disclosed, wherein the antistatic transmission unit is provided with a bearing extending along the axial direction, and the bearing is coated with the lubricating grease.

[0009] By adopting the above technical solution, grease can be applied to the bearings in the anti-static transmission unit to ensure smooth bearing rotation without dry friction, avoid mechanical sparks caused by bearing jamming or high temperature, and enhance the explosion-proof reliability of the transmission system.

[0010] According to another specific embodiment of the present invention, an explosion-proof exhaust cabinet is disclosed, wherein the buffer unit includes a first buffer pad and a second buffer pad, and along the first direction, the first buffer pad and the second buffer pad are respectively located on opposite sides of the antistatic counterweight unit.

[0011] By adopting the above technical solution, the first buffer pad and the second buffer pad can be respectively placed on opposite sides of the antistatic counterweight unit, so that the antistatic counterweight unit can be flexibly buffered when the window assembly moves up or down, thus comprehensively preventing hard impacts.

[0012] According to another specific embodiment of the present invention, an explosion-proof exhaust cabinet is disclosed. The cabinet further includes: a guide bracket, which is disposed on both sides of the working chamber along a second direction; the guide bracket extends along a first direction and is disposed facing the antistatic counterweight unit along a third direction, so that the antistatic counterweight unit can move relative to the guide bracket along the first direction; the second direction intersects the first direction and the third direction; along the first direction, the first buffer pad and the second buffer pad are disposed at intervals on the guide bracket and facing the antistatic counterweight unit.

[0013] By adopting the above technical solution, the movement of the anti-static counterweight unit can be precisely guided by the guide bracket, so that the anti-static counterweight unit can slide smoothly along the first direction without deviation. At the same time, the buffer pads are set at intervals on the guide bracket to ensure accurate and effective buffering position and avoid the anti-static counterweight unit directly impacting the cabinet.

[0014] According to another specific embodiment of the present invention, an explosion-proof exhaust cabinet is disclosed, wherein the antistatic counterweight unit includes: a body part connected to the antistatic synchronization unit; and a wear-resistant part disposed on the body part, wherein the wear-resistant part is slidably connected to the guide bracket.

[0015] According to another specific embodiment of the present invention, an explosion-proof ventilation cabinet is disclosed, wherein the first buffer pad and the second buffer pad are made of silicone or fluororubber.

[0016] According to another specific embodiment of the present invention, an explosion-proof exhaust cabinet is disclosed, wherein the material of the lubricating grease is perfluoropolyether grease.

[0017] According to another specific embodiment of the present invention, an explosion-proof ventilation cabinet is disclosed. The cabinet body includes a metal frame and an inner lining plate. The inner lining plate is installed on the metal frame and defines the working chamber. The explosion-proof ventilation cabinet further includes: a lighting device disposed in the working chamber, one end of the lighting device extending out of the inner lining plate; and an explosion-proof lighting switch disposed on the front wall of the cabinet body, the explosion-proof lighting switch being electrically connected to the other end of the lighting device.

[0018] According to another specific embodiment of the present invention, an explosion-proof ventilation cabinet is disclosed, which further includes at least one explosion-proof socket. Along a second direction, the at least one explosion-proof socket and the explosion-proof lighting switch are spaced apart on the front wall of the cabinet.

[0019] To make the above-mentioned contents of this utility model more obvious and understandable, preferred embodiments are described in detail below with reference to the accompanying drawings. Attached Figure Description

[0020] Figure 1A A perspective view of an embodiment of the explosion-proof air volume control system and explosion-proof exhaust cabinet of the present invention is shown.

[0021] Figure 1B This diagram shows a perspective view of an embodiment of the explosion-proof air volume control system and explosion-proof exhaust cabinet of the present invention. Figure 2 ;

[0022] Figure 1C Show Figure 1BA magnified view of a portion of region A in the middle;

[0023] Figure 1D A three-dimensional schematic diagram of an embodiment of the explosion-proof air volume control system and explosion-proof exhaust cabinet of the present invention is shown in Figure 3.

[0024] Figure 1E Show Figure 1D A magnified view of a portion of region B in the middle;

[0025] Figure 2 A perspective view of an embodiment of the explosion-proof air volume control system of the present invention is shown;

[0026] Figure 3A A perspective view of an explosion-proof air volume control system according to an embodiment of the present invention is shown, wherein the top cover of the explosion-proof box is not shown;

[0027] Figure 3B A cross-sectional schematic diagram of an explosion-proof airflow control system according to an embodiment of the present invention is shown, wherein the controller is not shown;

[0028] Figure 4 This diagram illustrates the structure of a controller, safety barrier, and explosion-proof displacement sensor according to one embodiment of the present invention.

[0029] Figure 5 A perspective view of another embodiment of the explosion-proof air volume control system of the present invention is shown;

[0030] Figure 6 A perspective view of another embodiment of the explosion-proof air volume control system and explosion-proof exhaust cabinet of this utility model is shown.

[0031] Figure 7 A perspective view showing another embodiment of the explosion-proof air volume control system and explosion-proof exhaust cabinet of this utility model. Figure 2 . Detailed Implementation

[0032] The following specific embodiments illustrate the implementation of this utility model. Those skilled in the art can easily understand other advantages and effects of this utility model from the content disclosed in this specification. Although the description of this utility model will be presented in conjunction with preferred embodiments, this does not mean that the features of this utility model are limited to this embodiment. On the contrary, the purpose of describing the utility model in conjunction with the embodiments is to cover other options or modifications that may be derived based on the claims of this utility model. To provide a deep understanding of this utility model, many specific details will be included in the following description. This utility model may also be implemented without using these details. Furthermore, to avoid confusion or obscuring the focus of this utility model, some specific details will be omitted in the description. It should be noted that, without conflict, the embodiments and features in the embodiments of this utility model can be combined with each other.

[0033] It should be noted that in this specification, similar reference numerals and letters in the following figures indicate similar items. Therefore, once an item is defined in one figure, it does not need to be further defined and explained in subsequent figures.

[0034] In the description of this embodiment, it should be noted that the terms "upper", "lower", "inner", "bottom", etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings, or the orientation or positional relationship that the utility model product is usually placed in during use. They are only for the convenience of describing the utility model and simplifying the description, and do not indicate or imply that the device or element 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.

[0035] The terms “first”, “second”, etc., are used only to distinguish descriptions and should not be interpreted as indicating or implying relative importance.

[0036] In the description of this embodiment, it should also be noted that, unless otherwise explicitly specified and limited, the terms "set up," "connected," and "linked" should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral connection; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium; and they can refer to the internal connection of two components. Those skilled in the art can understand the specific meaning of the above terms in this embodiment based on the specific circumstances.

[0037] To make the objectives, technical solutions, and advantages of this utility model clearer, the embodiments of this utility model will be described in further detail below with reference to the accompanying drawings.

[0038] refer to Figure 1AThis application provides an explosion-proof ventilation cabinet 100, including: an explosion-proof air volume control system 110, a cabinet 120, a window assembly 130, and a lighting device 140.

[0039] Among them, such as Figure 1A As shown, the explosion-proof fume hood 100 has a cabinet 120 with a working chamber 121, and a front opening 121a is formed on the front side of the working chamber 121 to open to the indoor environment. Exemplarily, the front opening 121a serves as an operating port. A viewing window assembly 130 is disposed on the front wall 122 of the cabinet 120, and the viewing window assembly 130 can be positioned along a first direction (e.g., the height direction of the cabinet 120, such as...). Figure 1A (As shown in the Z direction) Move upwards or downwards.

[0040] Continue to refer to Figure 1A The explosion-proof fume hood 100 also includes a support column 150. The support column 150 is along a second direction (e.g., the width direction of the cabinet body 120, such as...). Figure 1A (As shown in the X direction) The columns 150 are located on both sides of the working cavity 121. The columns extend along the first direction Z and are positioned along the second direction X towards the window assembly 130. Exemplarily, the column 150 includes a slide rail (not shown) extending along the first direction Z. The slide rail of the column 150 accommodates a slider (not shown) of the window assembly 130. The window assembly 130 is slidably connected to the column 150 via the slider, allowing the window assembly 130 to move relative to the column 150 along the first direction Z. Furthermore, the slider is located within the slide rail of the column 150, so that the column 150 limits the window assembly 130, preventing it from detaching from the column 150 and ensuring that the window assembly 130 can slide relative to the column 150 along the first direction Z.

[0041] For example, such as Figure 1A As shown, the window assembly 130 of this embodiment includes a glass window 131 and a window frame 132. The glass window 131 is installed within the window frame 132, which is positioned along the second direction X towards the column 150. The window frame 132 is equipped with a slider, which slidably connects the window frame 132 to the column 150, allowing the window frame 132 to slide relative to the column 150 along the first direction Z. Furthermore, the window frame 132 is made of aluminum alloy or antistatic modified polypropylene (PP), and its surface resistivity is 10 Ω·cm. 6 Ω to 10 9 Ω, thereby controlling the static electricity generated by friction when the window assembly 130 moves relative to the column 150, reducing the risk of explosion caused by frictional charging.

[0042] refer to Figure 1B The explosion-proof exhaust cabinet 100 in this embodiment of the application also includes a transmission assembly 160.

[0043] like Figure 1B Combination Figure 1C As shown, the transmission assembly 160 includes an anti-static transmission unit 161, an anti-static synchronization unit 162, and an anti-static counterweight unit 163. The anti-static synchronization unit 162 is sleeved on the anti-static transmission unit 161 and connected to both the viewing window assembly 130 and the anti-static counterweight unit 163. The anti-static synchronization unit 162 and the anti-static counterweight unit 163 are electrically connected, and the anti-static transmission unit 161 is electrically connected to the column 150, thus forming a grounding loop between the transmission assembly 160 and the column 150, preventing the local accumulation of static electricity generated by friction in the explosion-proof fume hood 100 of this embodiment.

[0044] Specifically, the antistatic synchronization unit 162 includes a first end 1621, a second end 1622, and a middle part 1625. The first end 1621 of the antistatic synchronization unit 162 is connected to the window assembly 130 (e.g., the window frame 132). The antistatic counterweight unit 163 is disposed on the back of the cabinet 120. The antistatic counterweight unit 163 is connected to the second end 1622 of the antistatic synchronization unit 162. The middle part 1625 of the antistatic synchronization unit 162 is located between the first end 1621 and the second end 1622.

[0045] Along the first direction Z, when the window assembly 130 moves upward, it drives the first end 1621 of the antistatic synchronization unit 162 to move upward, and the outer peripheral surface of the antistatic transmission unit 161 contacts and engages with the middle part 1625 of the antistatic synchronization unit 162 to drive the second end 1622 of the antistatic synchronization unit 162 and the antistatic counterweight unit 163 to move downward; when the window assembly 130 moves downward, it drives the first end 1621 of the antistatic synchronization unit 162 to move downward, and the second end 1622 of the antistatic synchronization unit 162 and the antistatic counterweight unit 163 to move upward through the antistatic transmission unit 161.

[0046] Exemplarily, the transmission assembly 160 in this embodiment further includes lubricating grease, which is coated on the middle portion 1625 of the antistatic synchronization unit 162, i.e., the lubricating grease is disposed between the middle portion 1625 of the antistatic synchronization unit 162 and the antistatic transmission unit 161. The antistatic transmission unit 161 has an axially extending bearing (not shown in the figure), which is also coated with lubricating grease. The lubricating grease in this embodiment is made of perfluoropolyether grease, which has excellent chemical inertness, high temperature resistance, and non-flammability, and will not react with flammable and explosive gases, eliminating the risk of ordinary lubricating grease decomposing and generating an ignition source under high temperature or friction. However, this is not a limitation; the material of the lubricating grease in this embodiment is not specifically limited and can be set according to actual conditions.

[0047] For example, such as Figure 1C As shown, the antistatic counterweight unit 163 includes a body portion 1631 and a connecting portion 1632. The connecting portion 1632 is disposed at one end of the body portion 1631 facing the second end 1622 of the antistatic synchronization unit 162. The connecting portion 1632 has a through hole 1633, so that the second end 1622 of the antistatic synchronization unit 162 bypasses the antistatic transmission unit 161 and passes through the through hole 1633 to connect with the body portion 1631 of the antistatic counterweight unit 163, so that the antistatic synchronization unit 162 and the body portion 1631 of the antistatic counterweight unit 163 are electrically connected.

[0048] For example, the antistatic synchronization unit 162 also includes a fastener 1623. The fastener 1623 passes through the second end 1622 of the antistatic synchronization unit 162 and connects to the body portion 1631 of the antistatic counterweight unit 163, so that the second end 1622 of the antistatic synchronization unit 162 is fixedly connected to the body portion 1631 of the antistatic counterweight unit 163, thereby ensuring the stability of the conductive connection between the antistatic synchronization unit 162 and the body portion 1631 of the antistatic counterweight unit 163.

[0049] For example, the antistatic synchronization unit 162 further includes a ring buckle 1624, which is sleeved between the portion of the antistatic synchronization unit 162 that passes through the through hole 1633 and the portion of the antistatic synchronization unit 162 that does not pass through the through hole 1633, so that the antistatic synchronization unit 162 forms a hook-like structure, fixing the upper edge of the through hole 1633 of the connecting portion 1632 into the hook, so that the antistatic synchronization unit 162 can drive the body portion 1631 of the antistatic counterweight unit 163 to move along the first direction Z.

[0050] Furthermore, the number of transmission components 160 in this embodiment includes two, and the two transmission components 160 are spaced apart on both sides of the working cavity 121 along the second direction X. Each transmission component 160 has an anti-static transmission unit 161 that includes components along the front-rear direction of the cabinet 120 (e.g., ...). Figure 1C Two synchronous pulleys are spaced apart (as shown in the Y direction). The anti-static synchronization unit 162 is a synchronous belt, the body 1631 of the anti-static counterweight unit 163 is a sheet metal part, and the fastener 1623 is a fastening screw. However, this application embodiment does not limit the number of transmission components 160 and anti-static transmission units 161, or the structure of anti-static transmission units 161, anti-static synchronization units 162, and anti-static counterweight units 163. They can be specifically set according to the actual situation. For example, the anti-static synchronization unit 162 can also be a steel wire rope.

[0051] For example, continue to refer to Figure 1CThe transmission assembly 160 in this embodiment further includes a conductive bracket 164 corresponding to the antistatic transmission unit 161. The conductive bracket 164 is disposed on the inner side of the column 150, and the antistatic transmission unit 161 (e.g., a synchronous pulley) is rotatably connected to the conductive bracket 164 along the second direction X, so that the antistatic transmission unit 161 is electrically connected to the column 150 through the conductive bracket 164.

[0052] For example, the conductive support 164 is made of aluminum alloy, the column 150 is an aluminum profile, and the outer side of the aluminum profile is coated with an antistatic coating. Furthermore, the antistatic transmission unit 161 is made of aluminum alloy, the antistatic synchronization unit 162 is made of antistatic modified polyurethane, and the surface resistance of both the antistatic transmission unit 161 and the antistatic synchronization unit 162 is 10 Ω·cm. 6 Ω to 10 9 Ω, thereby controlling the motion friction between the antistatic transmission unit 161 and the antistatic synchronization unit 162 of the transmission component 160 and the static electricity generated by the movement of the antistatic counterweight unit 163 relative to the cabinet 120 when the window component 130 moves relative to the column 150, so that the transmission component 160 and the column 150 form a grounding circuit, avoiding the local accumulation of static electricity generated by friction in the explosion-proof exhaust cabinet 100 of this application embodiment, and reducing the risk of explosion caused by friction electrification.

[0053] However, this application embodiment does not impose specific limitations on the materials of the antistatic transmission unit 161, antistatic synchronization unit 162, and antistatic counterweight unit 163 in the column 150, conductive bracket 164, and transmission assembly 160, and can be specifically set according to actual conditions. In other possible embodiments, for example, the material of the antistatic transmission unit 161 in this application embodiment can also be a low-polarity antistatic modified material such as antistatic modified polypropylene, and the material of the antistatic coating can be antistatic epoxy resin, etc.

[0054] refer to Figure 1D The explosion-proof exhaust cabinet 100 in this embodiment of the application also includes a grounding connector 170.

[0055] like Figure 1DAs shown, the grounding connector 170 includes multiple grounding cables 171 and a grounding terminal (not shown in the figure). The grounding terminal is used for grounding. One end of one of the grounding cables 171 is connected to the inside of the column 150, and the other end is used to connect to an external electrical system (such as the explosion-proof air volume control system 110 described later). This allows the external electrical system, column 150, window assembly 130, and transmission assembly 160 to form a grounding loop through the grounding connector 170. This combines the anti-static design of the main body of the explosion-proof exhaust hood 100 (such as the column 150, window assembly 130, and transmission assembly 160) with the explosion-proof design of the external electrical system, achieving an overall explosion-proof design for the explosion-proof exhaust hood 100. This significantly reduces the explosion-proof risk of the explosion-proof exhaust hood 100 and meets the requirements of explosion-proof standards.

[0056] For example, such as Figure 1C and Figure 1D As shown, the explosion-proof fume hood 100 of this application embodiment also includes a decorative panel 180. Specifically, the decorative panel 180 is disposed on the front wall of the cabinet 120. The decorative panel 180 is electrically connected to the column 150 through the grounding cable 171 of the grounding connector 170, so that the decorative panel 180 is electrically connected to the main body of the explosion-proof fume hood 100 through the grounding cable 171, so that the decorative panel 180 is connected to the grounding circuit of the explosion-proof fume hood 100, further reducing the risk of explosion caused by frictional electrification.

[0057] For example, the decorative panel 180 is a sheet metal part, and the outer side of the sheet metal part is provided with an anti-static coating. The material of the anti-static coating is anti-static epoxy resin, but it is not limited to this and can be specifically set according to the actual situation.

[0058] refer to Figure 1E and combined Figure 1D The explosion-proof exhaust cabinet 100 in this embodiment of the application also includes a buffer unit 190.

[0059] like Figure 1E As shown, the buffer unit 190 is disposed on the cabinet 120, wherein along the first direction Z, the buffer unit 190 is located between the anti-static counterweight unit 163 and the cabinet 120. Exemplarily, the buffer unit 190 of this application embodiment includes a first buffer pad 191 and a second buffer pad 192.

[0060] Specifically, along the first direction Z, the first buffer pad 191 and the second buffer pad 192 are located on opposite sides of the antistatic counterweight unit 163. For example... Figure 1E As shown, the first buffer pad 191 is located above the antistatic counterweight unit 163, and the first buffer pad 191 is disposed opposite to the body part 1631 of the antistatic counterweight unit 163. The second buffer pad 192 is located below the antistatic counterweight unit 163, and the second buffer pad 192 is disposed opposite to the body part 1631 of the antistatic counterweight unit 163.

[0061] For example, continue to refer to Figure 1E The cabinet 120 in this embodiment further includes guide brackets 125. The guide brackets 125 are disposed on both sides of the working cavity 121 along the second direction X, and each guide bracket 125 extends along the first direction Z and is disposed towards the anti-static counterweight unit 163 along the third direction Y, so that the anti-static counterweight unit 163 can move relative to the guide bracket 125 along the first direction Z. The guide brackets 125 can guide the anti-static counterweight unit 163 to move up and down, so that the upward or downward movement of the viewing window assembly 130 is smoother and more stable. Figure 1E As shown, the first buffer pad 191 and the second buffer pad 192 are spaced apart along the first direction Z at both ends of the guide bracket 125 and face the antistatic counterweight unit 163.

[0062] Therefore, when the viewing window assembly 130 is pushed to a preset position (e.g., the highest or lowest position), the antistatic counterweight unit 163 will first impact the first buffer pad 191 or the second buffer pad 192, rather than directly impacting the cabinet 120 (e.g., the metal frame). Furthermore, by providing a buffer unit 190 between the antistatic counterweight unit 163 and the cabinet 120, the explosion-proof fume hood 100 of this embodiment can effectively absorb the impact energy when the viewing window assembly 130 moves to a preset position (e.g., the highest or lowest position), eliminating hard impacts between the components and systematically eliminating ignition sources from a mechanical structure perspective, significantly improving the overall safety performance of the explosion-proof fume hood 100 in explosive hazardous environments.

[0063] For example, the guide bracket 125 has an L-shaped cross-section, such as... Figure 1E As shown, one side wall of the guide bracket 125 is fixedly connected to the cabinet 120, and the first buffer pad 191 and the second buffer pad 192 are spaced apart on one side wall of the guide bracket 125. The other side wall of the guide bracket 125 is arranged along the third direction Y towards the working cavity 121. However, it is not limited to this. The structure of the guide bracket 125 is not specifically limited in this embodiment, as long as the anti-static counterweight unit 163 can move along the extension direction of the guide bracket 125.

[0064] For example, the materials of the first buffer pad 191 and the second buffer pad 192 are silicone or fluororubber. Both of these materials have good elasticity, aging resistance and do not generate sparks upon impact. However, they are not limited to these materials. The materials of the first buffer pad 191 and the second buffer pad 192 can be selected according to the actual situation.

[0065] For example, such as Figure 1D and Figure 1EAs shown, the antistatic counterweight unit 163 also includes a wear-resistant component 1634, which is disposed on the side wall of the main body 1631 and electrically connected to the antistatic counterweight unit 163. Along the third direction Y, the wear-resistant component 1634 is located between the main body 1631 of the antistatic counterweight unit 163 and the other side wall of the guide bracket 125, i.e., the wear-resistant component 1634 is slidably connected to the guide bracket 125. The wear-resistant component 1634 not only reduces the contact area between the antistatic counterweight unit 163 and the guide bracket 125, increasing lubrication; furthermore, the wear-resistant component 1634 can be made of non-sparking materials such as copper alloy or ceramic to ensure that no frictional sparks are generated during sliding.

[0066] Continue to refer to Figure 1A The explosion-proof fume hood 100 is further equipped with an explosion-proof airflow control system 110 provided in this embodiment of the application on its cabinet 120. The explosion-proof airflow control system 110 is installed on ventilation equipment (such as the aforementioned explosion-proof fume hood 100 or ventilation room) to enable the ventilation equipment to dynamically adjust the exhaust volume of the explosion-proof airflow regulating valve 112 through the controller (not shown in the figure) in the explosion-proof airflow control system 110, thereby obtaining a stable face velocity and completely blocking the escape path of harmful media inside the cabinet, ensuring the safety of operators from the source. However, this is not limited to this; this application does not specifically limit the application scenarios of the explosion-proof airflow control system 110. Any application that can achieve face velocity control of the ventilation equipment through the explosion-proof airflow control system 110 provided in this embodiment of the application falls within the protection scope of this application. For example, the explosion-proof airflow control system 110 can be installed on a ventilation room with only left and right sliding doors.

[0067] Among them, such as Figure 1A As shown, the cabinet 120 also includes a fluid channel 123. The fluid channel 123 has a vent (not shown in the figure) and communicates with the working chamber 121 of the cabinet 120. The explosion-proof airflow regulating valve 112 of the explosion-proof airflow control system 110 is located at the vent and communicates with the fluid channel 123. Exemplarily, the fluid channel 123 is located at the top of the cabinet 120, but it is not limited thereto. The embodiments of this application do not specifically limit the structure and location of the fluid channel 123, and it can be specifically set according to the actual situation.

[0068] Combination Figure 2 As shown, the explosion-proof air volume control system 110 of this application embodiment includes: an explosion-proof box 111, a controller, a safety barrier (not shown in the figure), an explosion-proof air volume regulating valve 112, and an explosion-proof connector 113.

[0069] Specifically, the explosion-proof box 111 and the explosion-proof air volume regulating valve 112 are both located on the top of the cabinet 120. The explosion-proof box 111 is spaced apart from the fluid channel 123. The explosion-proof box 111 and the explosion-proof air volume regulating valve 112 are connected by an explosion-proof connector 113, and the explosion-proof air volume regulating valve 112 is connected to the working chamber 121.

[0070] For example, the explosion-proof airflow regulating valve 112 of this application embodiment has the functions of airflow detection and airflow regulation, and is an explosion-proof and intrinsically safe electrical device. Figure 2 As shown, the explosion-proof airflow regulating valve 112 includes an explosion-proof actuator 1121 and a valve body 1124. Furthermore, in this embodiment, the explosion-proof airflow regulating valve 112 uses an impeller-type flow sensor to detect flow rate, and its explosion-proof type is intrinsically safe. The explosion-proof airflow regulating valve 112 uses an explosion-proof actuator 1121 to regulate airflow, and the explosion-proof actuator is flameproof.

[0071] It is understood that the intrinsically safe type mentioned in the embodiments of this application refers to achieving explosion protection by limiting circuit energy, ensuring that the electric spark energy does not exceed the minimum ignition energy of the corresponding explosive medium under normal and fault conditions; the explosion-proof type mentioned in the embodiments of this application refers to achieving explosion protection through a high-strength shell and an explosion-proof joint surface. The shell can withstand the explosion pressure of the internal explosive mixture without damage; the joint surface is designed with specific gaps and lengths so that when the internal explosion flame and high-temperature gas pass through the gaps, they are cooled to below the ignition temperature by the shell, blocking the propagation to the external explosive environment. At the same time, the shell protection level is ≥IP54, which can prevent dust and water, and prevent the electrical components inside the shell (e.g., explosion-proof box 111) from being affected by external dust and liquids and causing malfunctions.

[0072] like Figure 2 As shown, the valve body 1124 includes a blade 1125 disposed within the valve body 1124, and the valve body 1124 has a first direction (i.e., Figure 2 The valve body 1124 has an inner cavity 1126 extending in the Z direction (as shown). Both ends of the valve body 1124 have openings communicating with the inner cavity 1126. The blade 1125 can rotate within the valve body 1124 to adjust the opening degree of the valve body 1124. An explosion-proof actuator 1121 is located outside the valve body 1124 and includes an explosion-proof housing 11211 and a drive unit (not shown in the figure). The drive unit is located inside the explosion-proof housing 11211 and connected to the blade 1125 for driving the blade 1125 to rotate.

[0073] refer to Figure 2 and Figure 3AThe explosion-proof box 111 of this application embodiment has a first interface 1111 and a second interface 1112, and the explosion-proof box 111 defines an explosion-proof cavity 1113. The controller 114 and the safety barrier 115 are both disposed in the explosion-proof cavity 1113. The controller 114 corresponds to the first interface 1111, and the safety barrier 115 is connected to the controller 114 and corresponds to the second interface 1112, so that the controller 114 corresponds to the second interface 1112 through the safety barrier 115.

[0074] Exemplarily, the explosion-proof box 111 of this application embodiment includes a box body 111a and a top cover 111b, wherein a first interface 1111 and a second interface 1112 are spaced apart on the side wall of the box body 111a, and the top cover 111b is sealed to the box body 111a and together with the box body 111a defines an explosion-proof cavity 1113. The explosion-proof box 111 is rectangular in shape, but this application embodiment does not limit the specific structure of the explosion-proof box 111; for example, it can also be a cube or a sphere.

[0075] For example, the explosion-proof connector 113 in this application embodiment is an explosion-proof flexible connector. However, it is not limited thereto, and the structure of the explosion-proof connector 113 is not specifically limited in this application embodiment. It can be understood that the first interface 1111 and the second interface 1112 in this application embodiment have the same structure. For ease of understanding, the first interface 1111 and the first cable 11212 will be used as examples for detailed description below.

[0076] like Figure 3B As shown, the first interface 1111 is opened in the box body 111a of the explosion-proof box 111. The inner wall of the first interface 1111 is provided with an internal thread. An explosion-proof gland is provided at the first interface 1111. The explosion-proof gland includes a connecting body 11111, a clamping nut 11112, a clamping ring 11113 and a sealing joint 11114. The outer surface of the connecting body 11111 is provided with external threads, and the inner wall of the sealing joint 11114 is provided with internal threads. The connecting body 11111 is threadedly connected to the inner wall of the first interface 1111 and the inner wall of the sealing joint 11114 respectively. The explosion-proof connector 113, which is sleeved on the first cable 11212, is threadedly connected to the inner wall of the sealing joint 11114, so that the end of the first cable 11212 passes through the clamping nut 11112, the clamping ring 11113 and the first interface 1111 and enters the explosion-proof cavity 1113. Tightening the sealing joint 11114 can drive the clamping ring 11113 to drive the clamping nut 11112 to press the connecting body 11111 and the first cable 11212 towards the first interface 1111, so as to achieve the function of fastening and sealing.

[0077] In other words, this application uses explosion-proof glands to secure and seal cables (e.g., the first cable, the second cable, the third cable, or cables connecting intrinsically safe explosion-proof devices). Furthermore, when the controller 114 is connected to the explosion-proof equipment via the corresponding first interface 1111, the explosion-proof connector 113, which is sleeved over the cable, provides a flexible transition and absorbs vibration, maintaining the overall explosion-proof and IP protection integrity of the explosion-proof system. Those skilled in the art will understand that when an explosion occurs inside one of the explosion-proof devices (e.g., the explosion-proof box 111 and the explosion-proof airflow regulating valve 112's explosion-proof actuator 1121) at either end of the explosion-proof connector 113, and flames (or pressure) enter the connector 113, it can withstand the pressure and cool the flames, preventing the explosion from propagating to the other explosion-proof device (e.g., the explosion-proof box 111), thus ensuring the integrity of the entire explosion-proof circuit.

[0078] Therefore, the controller 114 can be connected to the explosion-proof actuator 1121 of the explosion-proof airflow regulating valve 112 via the first interface 1111 and the explosion-proof connector 113, so as to realize the controller 114's control over the exhaust volume of the explosion-proof airflow regulating valve 112, dynamically adjusting the exhaust volume of the explosion-proof airflow regulating valve 112, so that the explosion-proof exhaust fan 100 can obtain a stable face velocity. It can be understood that the controller 114 is a high-voltage electrical device with multiple ports (see...). Figure 4 (It has a built-in relay, which poses a risk of generating electrical sparks.)

[0079] Based on this, the embodiments of this application enclose all components that may ignite an explosive gas mixture (such as controller 114) within a housing (i.e., explosion-proof box 111). Explosion-proof box 111 can withstand the explosion of flammable mixtures that penetrate into the interior of explosion-proof box 111 through any joint surface or structural gap without damage, and will not ignite an explosive atmosphere formed externally. Components that may generate sparks, arcs, and dangerous temperatures (such as controller 114) are all placed inside explosion-proof box 111, i.e., explosion-proof cavity 1113. Explosion-proof box 111 isolates the internal space of the equipment (i.e., explosion-proof cavity 1113) from the surrounding environment. Explosion-proof cavity 1113 is sealed to the outside, preventing the leakage of explosive media such as sparks and arcs within the explosion-proof cavity, and isolating explosive media such as sparks and arcs from contact with the outside air, thereby reducing the risk of explosion.

[0080] Furthermore, the explosion-proof box 111 and the explosion-proof actuator 1121 are connected together by an explosion-proof connector 113. The explosion-proof actuator 1121 has a first cable (not shown in the figure), which passes through the first interface 1111 and connects to the controller 114 and the explosion-proof actuator 1121 respectively, so that the explosion-proof actuator 1121 and the controller 114 are electrically connected, so that the controller 114 can adjust the air volume of the explosion-proof air volume regulating valve 112 through the explosion-proof actuator 1121, thereby realizing the function of dynamically adjusting the exhaust volume of the explosion-proof air volume control system 110.

[0081] Furthermore, the controller 114 in this embodiment can also be connected to the intrinsically safe explosion-proof device via the safety barrier 115 and the second interface 1112. It is understood that the safety barrier 115 in this embodiment is placed within a safe area (e.g., the explosion-proof cavity 1113 of the explosion-proof box 111 in this application) and is designed using intrinsically safe technology. It can limit the energy of the electrical signal transmitted from the controller 114 to the intrinsically safe explosion-proof device, so that the electrical signal, after energy constraint through the safety barrier 115, is provided to the intrinsically safe explosion-proof device via a cable through the second interface 1112.

[0082] Furthermore, this embodiment of the application, through the energy limiting and voltage stabilization function of the safety barrier 115, stabilizes the electrical signal provided by the controller 114 at a safe voltage and current, and divides the operating environment of the explosion-proof airflow control system 110 into a safe area (e.g., the explosion-proof cavity 1113) and an unsafe area (e.g., the outside of the explosion-proof box 111) through the explosion-proof connector 113. On the one hand, high-voltage equipment (potentially generating electrical sparks) is connected to the controller 114 inside the explosion-proof box 111 through the explosion-proof connector 113; on the other hand, the safety barrier 115 provides the energy-constrained electrical signal to an intrinsically safe explosion-proof device capable of operating at a safe voltage and current, thus achieving overall explosion-proof protection for the explosion-proof airflow control system 110. It is an explosion-proof and intrinsically safe electrical device that not only balances explosion-proof safety and energy consumption reduction but also improves exhaust stability.

[0083] Continue to refer to Figure 3A and combined Figure 2 For example, the number of safety barriers 115 in this application embodiment includes two, namely a displacement safety barrier 1151 and a screen safety barrier 1152, which are spaced apart in the explosion-proof cavity 1113. The number of intrinsically safe explosion-proof devices 116 in this application embodiment includes two, namely an explosion-proof displacement sensor 1161 and an explosion-proof touch screen 1162, wherein the explosion-proof displacement sensor 1161 is connected to the controller 114 through a corresponding second interface 1112 and the displacement safety barrier 1151, and the explosion-proof touch screen 1162 is connected to the controller 114 through a corresponding second interface 1112 and the screen safety barrier 1152.

[0084] It is understood that the embodiments of this application do not specifically limit the number of safety barriers 115 and second interfaces 1112. The number of safety barriers and second interfaces can correspond to the number of intrinsically safe explosion-proof devices. For example, in other possible implementations, the number of intrinsically safe explosion-proof devices in the embodiments of this application can be one, three, four or more, and the corresponding number of safety barriers and second interfaces can also be one, three, four or more.

[0085] Furthermore, in some possible implementations, the embodiments of this application may not include an intrinsically safe explosion-proof device. That is, the controller 114 of the embodiments of this application is connected to the explosion-proof air volume regulating valve or other explosion-proof devices only through the first interface 1111 and the explosion-proof connector 113.

[0086] The displacement safety barrier 1151 and the screen safety barrier 1152 have the same structure. However, due to the different electrical specifications of the explosion-proof displacement sensor 1161 and the explosion-proof touch screen 1162, the differences between the displacement safety barrier 1151 and the screen safety barrier 1152 lie in electrical parameters such as maximum output voltage, current, power, capacitance, and inductance. For ease of understanding, the following detailed explanation will use the displacement safety barrier 1151 and the explosion-proof displacement sensor 1161 as examples.

[0087] like Figure 4 As shown, the area within the dashed box (such as...) Figure 4 As shown in area A (i.e., the explosion-proof cavity 1113), the area inside represents the safe zone, and the area outside the dashed box A represents the unsafe zone. The controller 114 has ports 1141. Exemplarily, the number of ports 1141 may include multiple ports, which can be set according to actual conditions; this application does not make a specific limitation on this. The displacement safety barrier 1151 has a first end 115a and a second end 115b. The first end 115a of the displacement safety barrier 1151 is connected to port 1141 of the controller 114, and the second end 115b of the displacement safety barrier 1151 is electrically connected to the explosion-proof displacement sensor 1161 via a cable passing through a second interface (not shown in the figure).

[0088] For example, such as Figures 1A to 1C As shown, in this embodiment of the application, the explosion-proof displacement sensor 1161 is disposed on the top of the cabinet 120. The explosion-proof displacement sensor 1161 is connected to the anti-static synchronization unit 162 of the transmission assembly 160 to detect the distance the window moves along the first direction Z.

[0089] For example, such as Figure 1A As shown, the explosion-proof touch screen 1162 of this application embodiment is disposed on the cabinet 120 so that the user can read the variable air volume information (such as face wind speed) output by the explosion-proof touch screen 1162 or input control commands to adjust the exhaust volume.

[0090] Continue to refer to Figure 2In this embodiment of the application, the number of first interfaces 1111 includes three, the number of explosion-proof connectors 113 includes three, the three first interfaces 1111 are spaced apart on the side wall of the box 111a, and the three explosion-proof connectors 113 are respectively connected to the three first interfaces 1111 one by one.

[0091] The explosion-proof airflow control system 110 of this application embodiment further includes a second cable (not shown in the figure) and a third cable (not shown in the figure). Wherein, as Figure 2 As shown, the second cable passes through the corresponding explosion-proof connector 113 and connects to the controller 114 (see Figure 1111) via the corresponding first interface 1111. Figure 3A An electrical connection is made so that an external power source can be electrically connected to the controller via a second cable, which is used to supply power to the controller 114.

[0092] like Figure 1A and Figure 2 As shown, the lighting device 140 is installed inside the working chamber 121, and one end 141 of the lighting device 140 extends out of the top of the cabinet 120, that is, one end 141 of the lighting device 140 extends out of the inner lining plate 124. The third cable is passed through the corresponding explosion-proof connector 113 and is connected to the controller 114 (see...) through the corresponding first interface 1111. Figure 3A ( ) and electrically connected to the lighting device 140 via one end 141 of the lighting device 140.

[0093] For example, such as Figure 1A As shown, the explosion-proof fume hood 100 of this application embodiment also includes an explosion-proof lighting switch 143 and four explosion-proof sockets 144. Along the second direction X, the four explosion-proof sockets 144 and the explosion-proof lighting switch 143 are spaced apart on the front wall of the cabinet 120. The explosion-proof lighting switch 143 is electrically connected to the other end of the lighting device 140 to control the lighting device 140 to turn on or off. This application embodiment does not specifically limit the number of explosion-proof sockets 144; in other possible implementations, the number of explosion-proof sockets 144 can be one, two, three, or more. Furthermore, at least one explosion-proof socket 144 and explosion-proof lighting switch 143 in this application embodiment must be selected according to the corresponding explosion-proof type according to explosion-proof standards (such as GB 3836 series), for example, flameproof type. It is prohibited to reserve non-explosion-proof electrical interfaces, thus systematically eliminating ignition sources from an electrical perspective.

[0094] In the above embodiments, the number of explosion-proof air volume regulating valves 112 in the explosion-proof air volume control system 110 is one. However, this is not a limitation. The embodiments of this application do not specifically limit the number of explosion-proof air volume regulating valves 112 in the explosion-proof air volume control system 110. In other possible embodiments, the number of explosion-proof air volume regulating valves 112 can also be multiple. For example, the number of explosion-proof air volume regulating valves 112 can also be two, three, four or more.

[0095] refer to Figure 5 and Figure 6 In this embodiment, the difference from the above embodiment is that the explosion-proof air volume control system 110 has two explosion-proof air volume regulating valves 112, namely an explosion-proof air supply valve 1122 and an explosion-proof exhaust valve 1123, and the cabinet 120 of the explosion-proof exhaust cabinet 100 has two fluid channels 123, namely an air supply channel 1231 and an exhaust channel 1232 (see...). Figure 7 ).

[0096] like Figure 5 and Figure 6 As shown, the explosion-proof air supply valve 1122 is correspondingly installed at the ventilation opening of the air supply channel 1231, and the explosion-proof exhaust valve 1123 is correspondingly installed at the ventilation opening of the exhaust channel 1232. A part of the air supply channel 1231 is located at the top of the cabinet 120, and the explosion-proof box 111 is installed at the top of the air supply channel 1231. The explosion-proof actuators 1121 of the explosion-proof air supply valve 1122 and the explosion-proof exhaust valve 1123 are respectively connected to the explosion-proof box 111 through two explosion-proof connectors 113. Two first cables are passed through the corresponding explosion-proof connectors 113 and are electrically connected to the controller 114 in the explosion-proof box 111 through the corresponding first interface 1111.

[0097] refer to Figure 7 In this embodiment of the explosion-proof ventilation cabinet 100, the explosion-proof air valve (e.g., the explosion-proof air volume regulating valve 112, i.e., the explosion-proof make-up air valve 1122 and / or the explosion-proof exhaust valve 1123) is provided with a valve grounding terminal 1120, and the explosion-proof box 111 is provided with a grounding terminal 1110. The multiple grounding cables 171 of the grounding connector 170 are respectively connected between the column 150, the grounding terminal 1110, the air valve grounding terminal 1120, the cabinet 120 and the grounding terminal 172, so that the explosion-proof air volume control system 110 of this embodiment of the application and the main body of the explosion-proof ventilation cabinet 100 form a complete grounding circuit. This allows the explosion-proof ventilation cabinet 100 of this embodiment of the application to not only control the static electricity generated by the relative movement and friction of the main body components during use, reducing the risk of explosion caused by frictional charging, but also to provide a reliable grounding structure, ensuring that the user can easily ground the equipment on site. For example, the grounding resistance of the grounding terminal 172 of the grounding connector 170 is ≤4Ω.

[0098] For example, such as Figure 7 As shown, the explosion-proof exhaust cabinet 100 of this embodiment further includes a metal frame (not shown) and an inner lining plate 124 in its cabinet body 120. Specifically, the inner lining plate 124 is installed on the metal frame to define the working chamber 121. The explosion-proof air valve and the explosion-proof box 111 in the explosion-proof air volume control system 110 are both disposed on the upper surface of the inner lining plate 124, and the lighting device 140 is disposed in the working chamber 121. One end 141 of the lighting device 140 extends out of the inner lining plate 124 and is provided with a lighting grounding terminal 142. The lighting grounding terminal 142 is electrically connected to the air valve grounding terminal 1120 and the cabinet body 120 respectively through a grounding cable 171. That is, the lighting grounding terminal 142 is connected to the grounding circuit of the explosion-proof exhaust cabinet 100 through the grounding cable 171.

[0099] For example, in this embodiment of the application, the inner lining plate 124 is made of antistatic modified polypropylene material, and the surface resistivity of the inner lining plate is 10 Ω·cm. 6 Ω to 10 9 Ω. The metal frame of the cabinet 120 is made of austenitic stainless steel, such as 304 austenitic stainless steel or 316L austenitic stainless steel, which are non-magnetic and have low triboelectricity. It should be noted that the metal frame of the cabinet 120 in this embodiment of the application shall not be made of carbon steel, martensitic stainless steel, or other strongly magnetic and easily triboelectric materials.

[0100] In summary, this application embodiment installs an explosion-proof airflow control system on an explosion-proof fume hood, enabling the ventilation equipment to dynamically adjust the exhaust volume of the explosion-proof airflow regulating valve through the controller in the explosion-proof airflow control system, thereby obtaining a stable face velocity and completely blocking the escape path of harmful media inside the cabinet, ensuring the safety of operators from the source. On the one hand, high-voltage electrical equipment (which may generate electric sparks, such as the explosion-proof actuator of the explosion-proof airflow regulating valve) is connected to the controller inside the explosion-proof box through explosion-proof connectors. On the other hand, the energy-constrained electrical signal is provided to an intrinsically safe explosion-proof device (such as an explosion-proof displacement sensor or an explosion-proof touch screen) that can operate under safe voltage and current through a safety barrier, realizing the overall explosion-proof of the explosion-proof airflow control system. It is an explosion-proof and intrinsically safe electrical device that not only takes into account explosion-proof safety and reduces energy consumption, but also improves exhaust stability.

[0101] Furthermore, this embodiment of the application designs the main components of the explosion-proof fume hood (e.g., cabinet, column, window assembly, and transmission assembly) with anti-static and spark-free features. This allows for conductive connections between the column, window assembly, and transmission assembly via anti-static transmission units, anti-static synchronization units, and anti-static counterweight units; conductive connections between the anti-static transmission units and the column; and conductive connections between the column and the cabinet via grounding connectors, with grounding achieved through the grounding terminals of the grounding connectors. This forms a complete grounding loop, enabling the explosion-proof fume hood of this embodiment to not only control static electricity generated by relative movement and friction of components during use, reducing the risk of explosion due to frictional charging, but also to provide a reliable grounding structure, ensuring convenient grounding for users on-site.

[0102] Although the present invention has been illustrated and described with reference to certain preferred embodiments, those skilled in the art should understand that the above description is a further detailed explanation of the present invention in conjunction with specific embodiments, and should not be construed as limiting the specific implementation of the present invention to these descriptions. Those skilled in the art can make various changes in form and detail, including some simple deductions or substitutions, without departing from the spirit and scope of the present invention.

Claims

1. An explosion-proof fume hood, characterized in that, include: The cabinet has a working chamber; A window assembly is disposed on the front wall of the cabinet, and the window assembly is capable of opening in a first direction to form a front opening that opens to the interior environment; The transmission assembly includes an anti-static transmission unit, an anti-static synchronization unit, and an anti-static counterweight unit. The anti-static synchronization unit is sleeved on the anti-static transmission unit and is connected to the window assembly and the anti-static counterweight unit respectively. A buffer unit is disposed on the cabinet, along the first direction, the buffer unit is located above the antistatic counterweight unit, and / or the buffer unit is located below the antistatic counterweight unit.

2. The explosion-proof ventilation cabinet according to claim 1, characterized in that, The anti-static synchronization unit includes: The first end is connected to the window component; The second end bypasses the antistatic transmission unit and connects to the antistatic counterweight unit; The middle portion is located between the first end and the second end; The transmission assembly also includes: Lubricating grease is applied to the middle part of the antistatic synchronization unit.

3. The explosion-proof ventilation cabinet according to claim 2, characterized in that, The antistatic transmission unit is equipped with an axially extending bearing, which is coated with the lubricating grease.

4. The explosion-proof fume hood according to any one of claims 1 to 3, characterized in that, The buffer unit includes a first buffer pad and a second buffer pad, and along the first direction, the first buffer pad and the second buffer pad are located on opposite sides of the antistatic counterweight unit.

5. The explosion-proof ventilation cabinet according to claim 4, characterized in that, The cabinet also includes: A guide bracket is disposed on both sides of the working cavity along a second direction. The guide bracket extends along the first direction and is disposed facing the antistatic counterweight unit along a third direction, so that the antistatic counterweight unit can move relative to the guide bracket along the first direction. The second direction intersects the first direction and the third direction. Along the first direction, the first buffer pad and the second buffer pad are spaced apart on the guide bracket and face the antistatic counterweight unit.

6. The explosion-proof ventilation cabinet according to claim 5, characterized in that, The antistatic counterweight unit includes: The main body is connected to the anti-static synchronization unit; A wear-resistant component is disposed on the main body, and the wear-resistant component is slidably connected to the guide bracket.

7. The explosion-proof ventilation cabinet according to claim 4, characterized in that, The first and second cushioning pads are made of silicone or fluororubber.

8. The explosion-proof ventilation cabinet according to claim 2 or 3, characterized in that, The material of the grease is perfluoropolyether grease.

9. The explosion-proof ventilation cabinet according to claim 1, characterized in that, The cabinet includes a metal frame and an inner lining panel, the inner lining panel being installed on the metal frame and defining the working cavity; The explosion-proof ventilation cabinet also includes: A lighting device is provided in the working chamber, with one end of the lighting device extending out of the inner lining plate; An explosion-proof lighting switch is installed on the front wall of the cabinet, and the explosion-proof lighting switch is electrically connected to the other end of the lighting device.

10. The explosion-proof ventilation cabinet according to claim 9, characterized in that, The explosion-proof ventilation cabinet also includes at least one explosion-proof socket, and along the second direction, the at least one explosion-proof socket and the explosion-proof lighting switch are spaced apart on the front wall of the cabinet.