CN112827991A - Fume chamber with air supply structure - Google Patents

Abstract

Fume chamber with mend wind structure, including experimental brace table and the cabinet inner chamber of setting in brace table top, its characterized in that: the lower air supplementing device comprises an air passing channel capable of circulating and supplementing air, an air outlet of the air passing channel extends along the edge direction x of the supporting table, the air passing channel is used for supplementing air from the outside of the inner cavity of the cabinet to a nearby area on the table top of the supporting table, the lower air supplementing device further comprises an upper shell which forms a part of a channel wall body of the air passing channel and is positioned above the air passing channel, and on a flow path of the air supplementing, the upper shell comprises a first shell part, an intermediate transition shell part and a second shell part which are sequentially arranged, so that the air passing channel is correspondingly divided into a first section, an intermediate section and a second section which correspond to the first shell part, the intermediate transition shell part and the second shell part and are communicated with each other, wherein the external air enters from the first section, flows through the intermediate section and then flows out from the second section.

Description

Fume chamber with air supply structure

Technical Field

The invention relates to ventilation equipment for a laboratory, in particular to a ventilation cabinet with a wind supplementing structure.

Background

Various harmful gases are generated during the course of conducting chemical experiments, and it is necessary to be able to exhaust these toxic gases immediately and nearby. In order to immediately discharge harmful gas nearby, a fume hood is often used. The fume chamber belongs to the common local exhaust system in the chemistry experiment room, can remove a large amount of harmful gas with less amount of wind, and the diffusion of control harmful gas ensures laboratory staff's health and safety. As shown in fig. 10, the first common fume hood structure is shown, the common fume hood mainly comprises a supporting table 2 for test, an inner cabinet cavity 3 arranged above the supporting table 2 and used for carrying out experiment operation, and an exhaust fan (not shown in the figure) communicated with the inner cabinet cavity 3, wherein when the exhaust fan works, negative pressure is formed in the inner cabinet cavity 3, so that the quantity of harmful gas leaked outwards in the inner cabinet cavity 3 can be reduced, and the harmful gas is rapidly extracted from the inner cabinet cavity 3. An operation window 30 is arranged on the cabinet inner cavity 3, a lower air supplement channel 10 and a channel upper shell 1 used for forming an upper channel wall of the lower air supplement channel 10 are arranged at a threshold position of the operation window 30, the lower air supplement channel 10 belongs to a natural air supplement device, power for supplementing air is not increased through assistance of a fan and the like, the channel upper shell 1 comprises a front shell part 11, an intermediate shell part 12 and a rear shell part 13 which are respectively in a flat plate shape, the front shell part 11 is horizontally arranged, the rear shell part 13 is vertically arranged, and the intermediate shell part 12 is obliquely connected between the front shell part 11 and the rear shell part 13. An air outlet 15 of the lower air supplement channel 10 is formed between the front shell part 11 and the support platform 2, and an air inlet 14 of the lower air supplement channel 10 is formed between the rear shell part 13 and the support platform 2. When the exhaust fan is operated, air outside the cabinet cavity 3 enters the lower air supply channel 10 through the air inlet 14, and then enters the cabinet cavity 3 through the air outlet 15. A water blocking boss 21 is further arranged on the support platform 2. In addition, as shown in fig. 11, a second common fume hood structure is shown, in which the upper housing 1a of the duct shown in the figure includes a front housing portion 11a and a rear housing portion 12a that are joined together, the front housing portion 11a is a flat plate, the rear housing portion 12a is an arc plate, and other structures are similar to those shown in fig. 1 and will not be repeated. However, the air supplement effect of the two existing lower air supplement structures can be further improved.

Disclosure of Invention

As mentioned above, in the first conventional fume hood structure, when the exhaust fan works, a relatively weak negative pressure is formed in the inner cavity of the hood so that air in the inner cavity of the hood cannot escape from the operation window, at this time, external air flow can enter the inner cavity of the hood through the lower air supplement channel, but since the rear shell portion of the lower air supplement channel shown in fig. 10 is vertically arranged, part of the air flow entering the lower air supplement channel naturally flows vertically from bottom to top under the guidance of the rear shell portion, and then the flow direction is suddenly and forcibly changed, i.e., changed from outside to inside, due to inertia formed in the air flow in the process, the resistance is quite large when the flow direction is changed, a large number of vortexes are easily formed at the corner, and the air supplement amount passing through the lower air supplement channel to the area near the supporting platform surface is seriously hindered, so that the air supplement amount deposited on the supporting platform surface is further increased The danger of heavy molecular gases in the vicinity of the face flowing back out. Secondly, because of the unbalance of air pressure, the airflow entering the cabinet inner cavity forms a severe vortex near the air outlet, and the harmful gas in the cabinet inner cavity is easy to escape out of the ventilation cabinet under the entrainment action of the vortex, so that the health of operators is harmed. In the second conventional fume hood structure shown in fig. 11, although the upper duct casing can change the air flow from bottom to top to outside and reduce the resistance, compared with the upper duct casing, the air flow that can enter the lower air supply duct is still not ideal, and the poor vortex flow also occurs. Therefore, the air supply duct in the prior art needs to be corrected more scientifically and reasonably to further reduce the vortex generated by the air supply duct and improve the air outlet flow.

In order to achieve the technical purpose, the invention firstly provides a fume hood with an improved air supplement structure, which comprises a support platform for testing and a cabinet inner cavity arranged above the support platform, and is characterized in that: the air supply device also comprises a lower air supply device, the lower air supply device comprises an air passing channel which can circulate and supply air, an air outlet of the air passing channel extends along the edge direction x of the support platform, the air channel is used for supplying air from the outside of the cabinet inner cavity to the nearby area on the supporting platform surface, the lower air supplement device also comprises an upper shell which forms part of the channel wall body of the air passing channel and is positioned above the air passing channel, on the flow path of the supplementary air, the upper shell comprises a first shell part, an intermediate transition shell part and a second shell part which are arranged in sequence, so that the air passing channel is also divided into a first section, an intermediate section and a second section which correspond to the first shell part, the intermediate transition shell part and the second shell part and are communicated with each other, wherein the external air enters from the first road section and flows through the intermediate road section and then flows out from the second road section; viewed from a cross section direction perpendicular to the direction x, the inner side wall of the first shell part is a plane wall extending along the airflow direction in an inclined upward direction, the inner side wall of the intermediate transition shell part is an arc wall, and the inner side wall of the first shell part and the inner side wall of the second shell part are in smooth transition connection through the inner side wall of the intermediate transition shell part.

The inner cavity of the cabinet is an operation space for carrying out various experimental activities, and harmful gases generated in the experimental process can be temporarily collected in the inner cavity of the cabinet by virtue of the inner cavity of the cabinet, so that the harmful gases are prevented from flowing around.

The air passing channel is used for enabling external air flow of the inner cavity of the cabinet to supplement air to a nearby area on the table top of the supporting table, namely the air passing channel is an air supplementing channel for communicating the inner cavity of the cabinet with an external space, and the air passing channel is used for guiding external air of the inner cavity of the cabinet into the inner cavity of the cabinet, so that air can be supplemented to the inner cavity of the cabinet. In another embodiment, the air duct of the present invention may be applied to a structure in which a blower is installed at an inlet thereof or a duct communicating with the inlet thereof.

The air outlets of the air passing channels extend along the edge direction x of the supporting table, the extending direction of the air outlets of the air passing channels is defined to be basically consistent with the extending direction of the edge of the supporting table by the characteristics, and in practical application, the extending lengths of the air outlets of the air passing channels in the direction x can reach the positions of the left side wall and the right side wall of the inner cavity of the cabinet and are directly connected to the left side wall and the right side wall, and certainly can also be directly connected to the supporting table.

The inner side wall of the first shell portion is a planar wall which extends in the upward direction along the airflow direction in an inclined manner, namely the inner side wall of the first shell portion is not an arc wall, and the inner side wall of the first shell portion not only extends straightly from bottom to top, but also extends from outside to inside (from the outside direction of the cabinet inner cavity to the inside direction of the cabinet inner cavity). The planar wall can not only drain but also easily form a steady flow. And the inner side wall of the first shell part and the inner side wall of the second shell part are in smooth transition connection through the inner side wall of the intermediate transition shell part, so that the intermediate transition shell part can reduce the damage of flat-layer stable flow formed by the plane wall to the maximum extent.

According to the technical scheme, compared with the prior art, the invention has the beneficial technical effects that:

first, since the air channel is used for supplying air from the outside of the cabinet inner cavity to the nearby area on the supporting platform table top, the harmful gas sinking and accumulating on the nearby area on the supporting platform table top is favorably blown towards the inside of the cabinet inner cavity, and the amount of the harmful gas leaking outwards is reduced.

Secondly, because the inner side wall of the first shell part is a plane wall extending in an upward direction inclined along the airflow direction, at least part of the airflow entering the first section can flow from bottom to top under the guidance of the inner side wall of the first shell part and can also flow from outside to inside at the same time, namely, at least part of the airflow has kinetic energy of motion tendency flowing from bottom to top and also has kinetic energy of motion tendency flowing from outside to inside under the guidance of the inner side wall of the first shell part; secondly, the inner side wall of the first shell part is a plane wall, so that a stable flow is easy to form; in addition, because the inner side wall of the intermediate transition shell part is a circular arc wall, the inner side wall of the first shell part and the inner side wall of the second shell part are in smooth transition connection through the inner side wall of the intermediate transition shell part, so that at least part of gas can smoothly enter the second section from the first section under the guidance of the inner side wall of the intermediate transition shell part on a flow path from the first section to the intermediate section, and the defect that a large number of vortexes are formed in the intermediate section is effectively improved. Because the inner side wall of the upper shell is provided with the structure improvement point, external air flow can enter the air passing channel relatively more, so that more air flow can be supplemented into the cabinet inner cavity, and a large amount of vortex flow formed near the air outlet is reduced.

Secondly, further analysis of the first and second more conventional fume hood structures disclosed in the above background art section reveals that they all have a common structural feature, that is, they are provided with the flat front shell portion, and a part of the airflow blown out from the air outlet under the guidance of the front shell portion flows horizontally, and a part of the airflow flows upwards, but flows downwards and is greatly insufficient to the supporting platform, and thus the relatively heavy harmful gas sinking and accumulating on the supporting platform cannot be cleaned well. In order to solve the above technical problem, a further technical solution may be that an edge of the support platform is located at a height position that is shorter than a height position of the second housing portion, and an inner side wall of the second housing portion extends obliquely downward along an airflow direction so as to be capable of forcibly guiding at least a part of the airflow entering the second section to flow from top to bottom and then to pass through the air outlet to dive onto the support platform. Thus, the air flow volume blown out from the air outlet and diving from top to bottom and the impact force of the air flow can be relatively increased. The diving airflow can wash and clean the harmful gas deposited on the table top of the supporting table in a relatively strong way, and the harmful gas is pushed towards the inner direction of the inner cavity of the cabinet by utilizing the flow guiding function of the table top of the supporting table to be far away from the lower air supply device. Furthermore, the flowing range of the airflow can be expanded by utilizing the rebound effect of the supporting platform surface on the airflow, and the harmful gas floating in a certain height range away from the supporting platform surface is pushed towards the inner direction of the inner cavity of the cabinet. It can be seen that the catching ability of the hood against harmful gas is effectively optimized and the amount of harmful gas leaking to the outside is reduced by the obliquely downwardly extending structure of the inner side wall of the second case portion and in a very compact structure. The edge of the supporting platform is located at a height position that is shorter than the height position of the second shell portion, that is, in the up-down direction, the edge of the supporting platform is located below the second shell portion, for example, the edge of the supporting platform extends into the position right below the upper housing, specifically, the edge of the supporting platform may be located right below the second shell portion, or located right below the intermediate transition shell portion, and then located obliquely below the second shell portion; the edge of the support platform may be located outside the upper housing, so long as it can receive at least a portion of the airflow blown out from the outlet.

Secondly, further to the first, the more common fume chamber structure of second that disclose in the above-mentioned background art part carry out analysis discovery, they still have a common structural feature, be in promptly air outlet department all is provided with the boss that blocks water, the boss that blocks water can hinder the air current to the washing away of support mesa and lead to a large amount of harmful gas to remain in on the support mesa. In view of this, a further technical solution may be that a water blocking boss extending in a direction x is provided on the supporting base, and a reference line extending in an oblique direction of an inner side wall of the second case portion enters an inner space of the water blocking boss. According to the technical scheme, under the guidance of the inner side wall of the second shell part, at least part of air flow in the air passing channel can cross the water blocking boss to enter the inner space of the water blocking boss in a mode of diving from top to bottom to flush and clean harmful gas deposited on the supporting table top. In addition, the water-blocking boss can prevent liquid scattered on the support platform from dropping on the ground.

In a further aspect, an inner side wall of the second shell portion may be a planar wall. The structure of the inner side wall of the second shell part is not an arc-surface wall, so that the impact force of airflow diving from top to bottom is strengthened, and the flushing cleaning capability of the diving gas on harmful gas deposited on the table top of the supporting table is further improved; secondly, the processing procedure of the inner side wall of the second shell part can be simplified.

Besides, under the condition that the airflow does not need to be forced to dive onto the support platform from top to bottom through the inner side wall of the second shell part, the following technical scheme can be selectively adopted by the inner side wall of the second shell part:

the first technical scheme is as follows: the inner side wall of the second shell part extends obliquely upwards so as to guide at least part of air flow blown out from the air outlet to be blown from bottom to top. In this way, even if the water blocking boss is higher than the inner side wall of the second shell part, the air flow blown out from the air passing channel can still enter the nearby area on the supporting platform table surface under the guidance of the inner side wall of the second shell part.

The second technical scheme is as follows: the inner side wall of the second shell part extends horizontally so as to guide at least part of airflow blown out from the air outlet to blow horizontally.

In some cases, a part of the external air enters the cabinet cavity after flowing through the outer side wall of the second shell part, and in order to utilize the part of the external air to enhance the flushing and cleaning capability of harmful gases deposited on the supporting platform surface, a further technical scheme is that the outer side wall of the second shell part is a plane wall extending along the direction of the air flow in an inclined downward direction. Therefore, part of the external air is guided by the outer side wall of the second shell part to dive from top to bottom to the support platform to brush and clean harmful gas deposited on the table top of the support platform, and the outer side wall of the second shell part is a plane wall, so that the flushing capacity of air flow is enhanced. In addition, if the inner side wall of the second shell part extends downwards along the air flow direction in an inclined mode, two air flows which are respectively downwards blown onto the supporting platform from top to bottom are formed, and the two air flows are converged together to cooperatively push the harmful gas deposited on the table top of the supporting platform, so that the cleaning capability of the harmful gas deposited on the table top of the supporting platform is enhanced.

In some cases, a part of the external air may also flow through the outer side wall of the first shell portion and the outer side wall of the intermediate transition shell portion and then enter the cabinet cavity, and in order to enable the part of the airflow to be blown upwards, a further technical solution may be that the outer side wall of the first shell portion is a planar wall extending in an obliquely upward direction along the airflow direction, the outer side wall of the intermediate transition shell portion is an arc wall, and the outer side wall of the first shell portion and the outer side wall of the second shell portion are joined in a smooth transition manner through the outer side wall of the intermediate transition shell portion. In this way, a part of the outside air is blown from below to above under the guide of the outer side wall of the first housing part, so that the harmful gas floating at a certain height from the table top of the supporting table can be pushed forward away from the lower air supply device. Accordingly, under the guidance of the outer side wall of the upper shell, the external air flow can be divided into branch flows flowing upwards and downwards, and the cleaning range of the air flow on harmful gas is enlarged. In a specific application, the upper housing may be manufactured using a thin plate in order to simplify the structure and manufacturing process of the upper housing.

Further, according to the technical scheme, the upper shell covers at least part of the edge of the supporting platform, and the supporting platform becomes at least part of the lower wall body of the air passing channel. Thus, the lower air supplement structure of the fume hood is simplified. Wherein the upper housing may cover a part or all of the edge of the support table.

The upper shell further comprises a tail plate connected to the lower end of the first shell, the tail plate extends vertically in the up-down direction, an air inlet of the air passing channel is formed between the tail plate and the edge of the supporting table, and the air inlet is communicated with the outer space of the inner cavity of the cabinet. According to the technical scheme, the air inlet is arranged downwards, and when experimenters stand beside the lower air supplement device to perform experimental operation, the air inlet cannot be easily shielded by the bodies of the experimenters to damage the air supplement effect.

The technical scheme can also be that the cavity wall body for constructing the inner cavity of the cabinet comprises a left cavity side wall, a right cavity side wall and a cavity back wall positioned between the left cavity side wall and the right cavity side wall, wherein the left cavity side wall and the right cavity side wall are respectively arranged at the left side and the right side, the operation window is constructed on the opposite surface of the cavity back wall, and the operation window is used for forming an access channel for performing experiments on the supporting platform; the lower air supplement device is arranged at the lower threshold position of the door of the operation window, a movable cabinet door is arranged on the operation window, and the cabinet door is abutted to the upper shell when falling down. In this way, when the cabinet door completely closes the operation window, air outside the cabinet inner cavity can still be guided to supplement air to the nearby area on the supporting platform surface through the air passing channel.

The further technical scheme can also be that the head end and the tail end of the upper shell are respectively close to the left cavity side wall and the right cavity side wall of the inner cavity of the cabinet; the lower air compensating device further comprises plugs positioned at the head end and the tail end of the upper shell, the plugs comprise plug main bodies used for plugging the end parts of the air passing channels and plug connecting parts used for fixing the plug main bodies on the upper shell, and the plug main bodies of the plugs positioned at the head end and the tail end of the upper shell are respectively fixed on the left cavity side wall and the right cavity side wall. Therefore, the end part of the air passing channel can be plugged by the plug, and the lower air supplement device can be fixed. The cabinet is characterized in that the head end and the tail end of the upper shell are respectively close to the left cavity side wall and the right cavity side wall of the inner cavity of the cabinet, and a certain proper distance is also formed between the head end and the tail end of the upper shell which are respectively abutted against the left cavity side wall and the right cavity side wall of the inner cavity of the cabinet.

The lower air supplement device further comprises air guide fins extending along the flow path of the air supplement, and the air guide fins are arranged in the air passing channel. In this way, the airflow in the air passage is guided by the air guide fins, and the number and strength of the vortices formed in the air passage can be reduced.

The technical scheme can also be that the wind guide device further comprises a fin connecting piece, wherein one end of the fin connecting piece is connected with the wind guide fin, and the other end of the fin connecting piece is connected with the upper shell. The air guide fin is arranged on the air guide plate, and the fin connecting piece and the air guide fin can be of a split structure or an integrated structure.

Due to the characteristics and the advantages, the invention can be applied to the fume hood with the air supplementing structure.

Drawings

Fig. 1 is a schematic perspective view of a fume hood to which the present invention is applied;

FIG. 2 is a schematic structural view of a fume hood to which the present invention is applied in a front view;

FIG. 3 is a schematic sectional view taken along line A-A in FIG. 2;

FIG. 4 is an enlarged view of section C of FIG. 3;

fig. 5 is a schematic structural diagram of the flow guiding back plate in a front view direction, wherein the dotted line portions on the left and right sides respectively represent the left cavity side wall 31 and the right cavity side wall 32, and the dotted line portion below represents the supporting platform 2;

FIG. 6 is an enlarged view of portion B of FIG. 3;

fig. 7 is a schematic perspective view of the fixing base 8;

FIG. 8 is a schematic structural view of the lower air supplement device in a front view direction;

FIG. 9 is a schematic perspective view of the lower air supplement device after being turned over to the back;

FIG. 10 is a schematic view of a first, more conventional fume hood configuration;

figure 11 is a schematic view of a second, more conventional fume hood configuration.

Detailed Description

The structure of the fume hood applying the technical scheme of the invention is further explained by combining the attached drawings.

As shown in fig. 1 to fig. 3 and fig. 5, the present invention relates to a fume hood, which includes a test support platform 2, a cabinet inner cavity 3 disposed above the support platform 2, and a cavity wall body configured as the cabinet inner cavity 3, wherein the cavity wall body includes a left cavity side wall 31, a right cavity side wall 32, and a cavity back wall 34 and a cavity top wall 33 disposed between the left cavity side wall 31 and the right cavity side wall 32. The gas experiment device is characterized by further comprising an operation window 30 which is built on the back wall 34 of the cavity, the operation window 30 extends left and right along the front side edge 22 of the supporting platform 2, the operation window 30 is used for forming an access channel for experiments on the supporting platform 2, hands of experimenters can penetrate through the operation window 30 to extend into the inner cavity 3 of the cabinet for various experimental operations, and harmful gas generated in the experimental process can be temporarily collected in the inner cavity 3 of the cabinet to avoid fleeing all around. A total air outlet 330 is further arranged on the cavity top wall 33, and the total air outlet 330 is used for discharging air in the cabinet inner cavity 3; in other embodiments, the total exhaust vent 330 may also be disposed at a suitable position on the left chamber sidewall 31, the right chamber sidewall 32 or the chamber back wall 34, and the specific location may be determined according to the flow field design of the whole airflow flow of the fume hood.

An exhaust channel 6 communicated with the main exhaust outlet 330 is arranged in the cabinet inner cavity 3. An exhaust fan (not shown in the figure) communicated with the general exhaust outlet 330 is further installed above the fume hood, and the exhaust fan is used for forming negative pressure in the cabinet inner cavity 3. During operation of the suction fan, harmful gases accumulated in the cabinet interior 3 are sucked into the exhaust duct 6 and then discharged through the main exhaust outlet 330.

The basic safe use goal of the fume hood is that under the suction force of the exhaust fan, the design of an airflow field in the whole hood ensures that the surface wind speed at the position of the operation window 30 is stable and uniform, the gas in the inner cavity 3 of the hood cannot flow back from the position of the operation window 30, and macromolecular harmful gas deposited at the bottom of the inner cavity 3 of the hood can be timely discharged and cannot flow back, and the specific schemes for realizing the basic goals are many, and the scheme provided by the invention is not the only scheme; secondly, to achieve the basic objectives described above, it is desirable to modify the various partial structures so that they function in a fume hood product. Therefore, the invention mainly improves the partial structure of the fume hood so as to achieve the corresponding technical effect, and the corresponding partial improvement schemes are explained in the following statements one by one.

In order to achieve the basic objective, the invention firstly improves the air passing structure at the lower part of the flow guide back plate 5. As shown in fig. 3, the airflow guiding back plate 5 is disposed in the cabinet inner cavity 3, the airflow guiding back plate 5 and the cavity wall body of the cabinet inner cavity 3 are in a split structure, the airflow guiding back plate 5 is located in front of the cavity back wall 34 with a space therebetween to form the exhaust duct 6, and for this reason, the airflow guiding back plate 5 actually faces the operation window 30.

As shown in fig. 5, the flow guide back plate 5 includes a first flow guide back plate 51 disposed above the support platform 2 and close to the support platform 2, the first flow guide back plate 51 and the cavity back wall 34 are disposed substantially parallel to each other, but in other embodiments, the first flow guide back plate 51 may be disposed obliquely with respect to the cavity back wall 34. The first deflector back plate 51 is located in front of the cavity back wall 34 with a space therebetween to form a first exhaust duct 61 extending up and down, and the first exhaust duct 61 forms a partial passage of the exhaust duct 6. The left and right side edges of the first flow guiding back plate 51 extend to be close to the left cavity side wall 31 and the right cavity side wall 32 in the left-right direction, respectively, but a gradually enlarged overfire air opening 71 and a gradually enlarged overfire air opening 71a are respectively arranged between the two side edges of the first flow guiding back plate 51 located in the lower region of the cabinet inner cavity 3 and the left cavity side wall 31 and the right cavity side wall 32, that is, the gradually enlarged overfire air opening 71 and the gradually enlarged overfire air opening 71a are located on the left and right sides of the lower region of the cabinet inner cavity 3, and the gradually enlarged overfire air opening 71a belong to the enlarged overfire air opening. The gradually-enlarged overfire air opening 71 and the gradually-enlarged overfire air opening 71a have a geometry gradually enlarged from the upper portion to the lower portion. In one preferred embodiment, the maximum width W of the gradually-enlarged overfire air opening 71 and the gradually-enlarged overfire air opening 71a in the left-right direction is 35mm to 45mm, and may be 35mm, 40mm or 45mm, for example. In addition, the two sides of the upper region of the first deflector back plate 51 are not spaced from the left and right cavity side walls 31 and 32 by a large distance, and specifically include an upper gap 76 and an upper gap 76a with uniform gap width, the upper gap 76 is located above the gradually enlarged overfire air opening 71, and the upper gap 76a is located above the gradually enlarged overfire air opening 71 a. The gap width W4 of the upper side gap 76 and the upper side gap 76a is smaller than the width of the gradually enlarged overfire air opening 71 and the gradually enlarged overfire air opening 71a, the gap width W4 of the upper side gap 76 and the upper side gap 76a is also smaller than the gap height H of the bottom space 7 to be discussed below, the gap width W4 is generally 1mm to 20mm, such as 1mm, 10mm and 20mm, and the specific gap size is determined by other specific air inlet structures of the fume hood, the air draft power of the air draft fan, the application range of the fume hood and other factors. Gaps with uniform width in the left-right direction between the two sides of the second flow guide back plate 52 and the third flow guide back plate 53 and the left cavity side wall 31 and the right cavity side wall 32, which will be discussed below, are also W4.

According to the technical scheme, compared with the prior art, the beneficial technical effects are that: firstly, because the gradually enlarged air passing openings 71 and 71a are respectively formed between the two side edges of the first flow guide back plate 51 located in the lower region of the cabinet inner cavity 3 and the left cavity side wall 31 and the right cavity side wall 32, that is, relatively large air guiding vacancies consecutively arranged from top to bottom are respectively formed on the left side and the right side of the first flow guide back plate 51, so that a flow channel can be provided for timely discharging relatively heavy macromolecular gases sinking and accumulating at the left side and the right side corners of the lower region of the cabinet inner cavity 3 into the first air discharging channel 61, and the flow channel is also beneficial to reducing the resistance of airflow flow and the formation of vortex, and improving the airflow flow speed. Secondly, when the fume hood is configured to use the suction flow as the control air flow and form an air pressure gradient gradually increasing from bottom to top in the cabinet inner cavity 3, a certain suction speed gradient exists between the highest position and the lowest position of the gradually enlarged air passing opening 71, and the shape change of the gradually enlarged air passing opening 71, namely the shape change of the gradually enlarged air passing opening 71, which is a geometric shape gradually increasing from the upper part to the lower part, is beneficial to forming a basically uniform suction amount (air passing amount) on the gradually enlarged air passing opening 71, so that the distribution state of the air flow fields at the left and right side corners of the lower area of the cabinet inner cavity 3 can be optimized, and the generation of vortex can be further reduced. In addition, compared with the gap with the uniform width from top to bottom in the prior art, the air passing area of the lower part of the gradually enlarged air passing opening 71 is relatively larger, so that the air passing amount of the lower part of the gradually enlarged air passing opening 71 is relatively larger, and more relatively heavy macromolecule gas sinking and accumulating at the left corner of the lower area of the cabinet inner cavity 3 can be captured. The gradually enlarged overfire air opening 71a can achieve the same technical effects as the gradually enlarged overfire air opening 71, and the discussion thereof will not be repeated.

As shown in fig. 5, the first deflector back plate 51 is close to the supporting platform 2 and is spaced apart from the supporting platform so as to have a bottom space 7 between the first deflector back plate 51 and the supporting platform 2, and the gap widths W4 of the upper side gap 76 and the upper side gap 76a are respectively smaller than a gap height H of the bottom space 7, in a preferred embodiment, the gap height H is generally 30mm to 150mm, such as 30mm, 68 mm, 88 mm or 150mm, and the specific gap height is determined according to other specific air intake structures of the fume hood, the air draft power of the air draft fan, the application range of the fume hood, and the like. According to the technical scheme, the bottom air guide passage is formed by the bottom space 7, so that heavy macromolecular gas sinking into the lower area of the inner cavity 3 of the cabinet can be captured. In other embodiments, the bottom space 7 may be set to be close to zero, i.e., the bottom end surface of the first deflector back plate 51 stands on the support table 2. Further, the gradually enlarged overfire air opening 71 and the gradually enlarged overfire air opening 71a respectively extend downward through the bottom end surface of the first deflector back plate 51 so as to be combined with the bottom space 7. In this way, the gradually-enlarged overfire air opening 71a and the bottom space 7 are combined to form a U-shaped bottom total overfire air space, so that the relatively heavy macromolecular gases deposited in the lower region of the cabinet inner cavity 3 can be better captured. In addition, it is convenient to machine the gradually-enlarged overfire air opening 71 and the gradually-enlarged overfire air opening 71a on the first deflector back plate 51.

In order to form the gradually-enlarged overfire air opening 71 and the gradually-enlarged overfire air opening 71a, the following technical scheme, the first technical scheme, may be further selected: as shown in fig. 5, two side edges of the first deflector back plate 51 located in the lower region of the cabinet inner chamber 3 are inclined and narrow in opposite directions, and the left chamber side wall 31 and the right chamber side wall 32 are vertical. In the present embodiment, a first technical solution is adopted, where the gradually-enlarged overfire air opening 71 and the gradually-enlarged overfire air opening 71a are in the shape of a right triangle, and a vertex angle Q thereof is 3 ° to 13 °, for example, 3 °, 6 °, and 13 °. Second solution (not shown in the figure): the lower regions of the left cavity side wall 31 and the right cavity side wall 32 are respectively in a shape gradually sinking outwards from top to bottom, and two side edges of the first flow guide back plate 51 located in the lower region of the cabinet inner cavity 3 are in a vertical shape.

In order to achieve the above basic object, the present invention provides another improvement to the structure of the deflector back plate 5, which can be used alone or in combination with the gradually enlarged air passing opening 71 and the gradually enlarged air passing opening 71a in the ventilation hood product. Specifically, as shown in fig. 5, the flow guide back panel 5 is provided with a flow guide structure capable of guiding the airflow in the front space 35 into the exhaust duct 6, that is, only the panel body located in the lower region of the cabinet inner cavity 3 is provided with a lower air guide passage 72 extending left and right on the first flow guide back panel 51, and the air passing area of the lower air guide passage 72 is not larger than the air passing area of the bottom space 7, that is, the air passing area of the lower air guide passage 72 may be equal to or smaller than the air passing area of the bottom space 7. In this way, the lower air guiding duct 72 is also located in the lower region of the cabinet interior 3, so that the comparatively heavy macromolecular gases which sink and accumulate in the lower region of the cabinet interior 3 can be discharged in time. In addition, compared with the case that a plurality of rows of wind guide slots are arranged on the lower area of the first flow guide back plate 51, the air passing rate of the lower wind guide passageway 72 is relatively stronger, so that not only can harmful gas floating to the area nearby be better captured, but also suitable air passing rate providing conditions are configured for the gradually enlarged air passing opening, the flow guide structure of the first flow guide back plate 51 can be greatly simplified, the damage to the original structural strength of the first flow guide back plate 51 is reduced, and the processing of the first flow guide back plate 51 is facilitated. Further, the lower air guiding passage 72 includes at least three first sub-passages, that is, a plurality of first sub-passages, that is, 3 or 4 first sub-passages. In the present embodiment, three first sub-aisles, namely, a first sub-aisle 72a, a first sub-aisle 72b, and a first sub-aisle 72c are provided, and the three first sub-aisles are arranged left and right and each of the first sub-aisles has an elongated shape extending in the left-right direction. According to the above-described configuration, the first baffle 51 can maintain a suitable structural strength even when the lower air guiding duct 72 is formed.

In order to achieve the above basic object, the present invention provides another improvement to the structure of the deflector back plate 5, which can be used alone or in combination with the gradually enlarged air passing opening 71 and the gradually enlarged air passing opening 71a in the ventilation hood product. Specifically, as shown in fig. 3 and 5, the flow guide back plate 5 further includes a second flow guide back plate 52 separated from the first flow guide back plate 51, the second flow guide back plate 52 is located above the first flow guide back plate 51 and is arranged close to the first flow guide back plate 51, the second flow guide back plate 52 is located in front of the cavity back wall 34 and is arranged substantially parallel to each other with a space therebetween so as to form a second exhaust duct 62 extending vertically, and the second exhaust duct 62 also forms a partial channel of the exhaust duct 6 (in other embodiments, the second flow guide back plate 52 may also be arranged obliquely with respect to the cavity back wall 34). The cabinet further comprises a middle air guide passage 73 extending from left to right, the middle air guide passage 73 is formed by an inter-plate distance 73 between the first air guide back plate 51 and the second air guide back plate 52, the middle air guide passage 73 is approximately located in a central area of the cabinet inner cavity 3 viewed in the up-down direction, and an air passing area of the middle air guide passage 73 is smaller than an air passing area of the lower air guide passage 72. Compared with the prior art, the beneficial technical effects of the technical scheme are as follows: firstly, as the bottom space 7 capable of passing the wind is arranged between the first flow guide back plate 51 and the support table 2, the heavier macromolecular gases sinking and accumulating in the lower area of the inner cavity of the cabinet can be timely discharged by utilizing the bottom space 7; secondly, because the lower air guiding passage 72 is located in the lower region of the cabinet inner cavity 3 and above the bottom space 7, the heavier macromolecular gas escaping from the bottom space 7 and continuing to drift upward can be captured and carried into the air duct behind the air guiding back plate 5 by the air flow flowing through the lower air guiding passage 72, and moreover, because only one lower air guiding passage 72 is arranged on the first air guiding back plate 51, and the air passing area of the lower air guiding passage 72 is not larger than that of the bottom space 7, compared with the case that a plurality of rows of air guiding ducts are arranged on the first air guiding back plate 51, the air passing amount of the lower air guiding passage 72 is relatively stronger, so that the harmful gas drifting to the vicinity of the lower air guiding passage can be better captured, and the bottom space 7 can have a proper air passing amount; furthermore, the middle air guiding passage 73 is formed by the inter-plate distance between the first air guiding back plate 51 and the second air guiding back plate 5, so that the middle air guiding passage 73 can have a proper air passing area by controlling the inter-plate distance, especially a narrow air guiding gap can be formed in a very simple and convenient manner, the ventilation area of the middle air guiding passage 73 is not limited by the dimension and specification of a milling tool, and the middle air guiding passage 73 can be flexibly configured. The relatively light noxious gases escaping from the lower air guiding passage 72 and continuing to drift upward can be captured by the air flow passing through the middle air guiding passage 73 and carried into the air duct behind the air guiding back plate 5. Accordingly, it can be found that the bottom space 7, the lower air guide passage 72 and the middle air guide passage 73 are sequentially arranged from bottom to top, and appropriate ventilation areas, numbers and layout positions are configured for the bottom space, the lower air guide passage and the middle air guide passage, so that harmful gases with different weights can be effectively captured, the flow guide structure of the flow guide back plate 5 can be greatly simplified, damage to the original structural strength of the flow guide back plate 5 is reduced, and the flow guide back plate 5 is convenient to process.

As shown in fig. 5, the flow guide back plate 5 further includes a third flow guide back plate 53 located above the second flow guide back plate 52, and the third flow guide back plate 53 is located in front of the cavity back wall 34 and may be substantially parallel to the cavity back wall 34. In other embodiments, the third baffle plate 53 may be disposed obliquely to the cavity back wall 34. A space is formed between the third flow guiding back plate 53 and the cavity back wall 34 to form a third exhaust duct 63 extending up and down, and the first exhaust duct 61, the second exhaust duct 62 and the third exhaust duct 63 are connected front to back to form an exhaust duct 6 leading to the main exhaust port 330. The lower end of the third baffle plate 53 is connected to the upper portion of the second baffle plate 52, and the third baffle plate 53 is disposed under the total exhaust outlet 330 in an inclined upward structure so that the third exhaust duct 63 is connected to the total exhaust outlet 330. A splicing seam 74 is arranged between the second flow guide back plate 52 and the third flow guide back plate 53, the air passing area of the splicing seam 74 is not larger than the air passing area of the inter-plate space 73, and no air passing hole slot is arranged on the second flow guide back plate 52 or the third flow guide back plate 53. According to the above technical solution, compared with the solution that the air passing hole slots are provided on both the second flow guide back plate 52 and the third flow guide back plate 53, the bottom distance 7, the lower air guide passage 72, the middle air guide passage 73, and the air passing amount of the gradually enlarged air passing opening are advantageously increased, so that the capturing capability of the harmful gas deposited in the lower area and the central area of the cabinet inner cavity 3 can be maintained while simplifying the flow guide structure on the flow guide back plate 5. The air area of the splicing seam 74 is not larger than the air area of the middle air guiding passage 73, that is, the air area of the splicing seam 74 is smaller than or equal to the air area of the middle air guiding passage 73, and the air area of the splicing seam 74 may even be zero, for example, in the case of sealing by means of a sealing member. In addition, a top space 75 is formed between the upper end of the third deflector back plate 53 and the cavity top wall 33 of the cabinet inner cavity 3. According to the above technical solution, the top space 75 is actually located in the upper region of the cabinet inner cavity 3, so that the harmful gas continuously drifting upwards away from the bottom space 7, the lower wind guiding passage 75 and the middle wind guiding passage 73 in sequence can be caught by the airflow flowing through the top space 75 and brought into the third exhaust duct 63 to be discharged out of the cabinet inner cavity 3.

As shown in fig. 3, 6 and 7, in order to fix the deflector plate 5, a fixing seat 8a and a fixing seat 8b are disposed between the deflector plate 5 and the cavity back wall 34. The structures of the fixing seat 8, the fixing seat 8a and the fixing seat 8b are the same, and the fixing seat 8 is taken as an example for description below. Fixing base 8 is the U-shaped, is in including top support wall 83 and setting left support wall 81, the right support wall 82 of the left and right both sides of top support wall 83 with be formed with intermediate layer chamber 80 between left support wall 81, the right support wall 82 be provided with spliced pole 85 on the top support wall 83, spliced pole 85's afterbody stretches into in the intermediate layer chamber 80, fixing base 8 through screw locking in on the chamber back of the body wall 34. The fixing base 8 is located between the second baffle plate 52 and the cavity back wall 34, the second baffle plate 52 abuts against the top supporting wall 83, and a fastening member 86 penetrates through the second baffle plate 52 and is connected to the connecting column 85 so as to fix the second baffle plate 52 on the fixing base 8; an inclined insertion groove 84 is formed on the top support wall 83, and the lower end of the third deflector plate 53 is inserted into the inclined insertion groove 84 to be engaged with the upper portion of the second deflector plate 52. The fixed seat 8a is arranged between the first flow guide back plate 51 and the cavity back wall 34, the first flow guide back plate 51 abuts against the top supporting wall of the fixed seat 8a, and a fastener penetrates through the first flow guide back plate 51 to be connected to a connecting column of the fixed seat 8a so as to fix the first flow guide back plate 51 on the fixed seat 8 a. Therefore, the installation, the disassembly and the replacement of the first flow guide back plate 51, the second flow guide back plate 52 and the third flow guide back plate 53 are simplified.

As shown in fig. 2, 3 and 4, the pass-through cabinet is further provided with a lower air supplement device, the lower air supplement device comprises an air passage 10 through which the supplement air can flow, an air outlet 15 of the air passage 10 is arranged to extend along a direction X of an edge 22 of the support platform 2 (wherein, the direction X is the direction of the X axis in fig. 2), the air passage 10 is used for supplementing the air from the outside of the cabinet inner cavity 3 to a nearby area on the top of the support platform 2, the lower air supplement device further comprises an upper shell 1 forming a partial passage wall of the air passage 10 and located above the air passage 10, and on the flow path of the supplement air, the upper shell 1 comprises a first shell part 11, a middle transition shell part 13 and a second shell part 12 which are arranged in sequence, so that the air passage 10 is correspondingly divided into a first section 101, a second section, and a second section 13 and a second section 12 which are communicated with the first shell part 11, the middle transition shell part 13 and the second shell part 12, An intermediate section 103 and a second section 102, wherein outside air enters from the first section 101 and flows through the intermediate section 103 and then flows out from the second section 102; viewed from a cross-sectional direction perpendicular to the direction x (i.e., as shown in fig. 4), the inner side wall 11a of the first shell portion 11 is a planar wall extending in an obliquely upward direction along the gas flow direction, the inner side wall 13a of the intermediate transition shell portion 13 is an arc wall, and the inner side wall 11a of the first shell portion 11 and the inner side wall 12a of the second shell portion 12 are joined in smooth transition through the inner side wall 13a of the intermediate transition shell portion 13.

Wherein, the air outlet 15 of the air passage 10 extends along the direction x of the edge 22 of the support platform 2, and the above-mentioned characteristics define that the extending direction of the air outlet 15 of the air passage 10 is substantially consistent with the extending direction of the edge 22 of the support platform 2. Secondly, the air channel 10 is used for guiding the air outside the cabinet inner cavity 3 to supplement air to the nearby area on the table top of the supporting table 2, that is, the air channel 10 is a wind supplementing channel for communicating the cabinet inner cavity 3 with the external space, and the air channel 10 is used for guiding the external air of the cabinet inner cavity 3 into the cabinet inner cavity 3, so as to supplement air to the cabinet inner cavity 3. The inner wall 11a of the first casing portion 11 is a planar wall extending in an upward direction inclined in the airflow direction, that is, the inner wall 11a of the first casing portion 11 is not an arc wall, and the inner wall 11a of the first casing portion 11 extends not only straight from the bottom to the top but also from the outside to the inside (from the outside of the cabinet interior 3 to the inside of the cabinet interior 3). The planar wall can not only drain but also easily form a steady flow. And the inner side wall 11a of the first shell portion 11 and the inner side wall 12a of the second shell portion 12 are in smooth transition connection through the inner side wall 13a of the intermediate transition shell portion 13, so that the intermediate transition shell portion 13 can reduce the damage to the flat-bed stable flow formed by the plane walls to the maximum extent.

Compared with the prior art, the beneficial technical effect that the above-mentioned technical scheme that air supplement device adopted down lies in: firstly, since the air duct 10 is used to supply air from the outside of the cabinet interior 3 to the vicinity of the table top of the supporting table 2, it is advantageous to blow the harmful gas sinking to the vicinity of the table top of the supporting table 2 toward the inside of the cabinet interior 3, thereby reducing the amount of the harmful gas leaking to the outside. Secondly, since the inner side wall 11a of the first shell portion 11 is a planar wall extending in an upward direction inclined along the airflow direction, at least a part of the airflow entering the first path section 101 can flow not only from bottom to top but also from outside to inside under the guidance of the inner side wall 11a of the first shell portion 11, that is, at least a part of the airflow has not only kinetic energy of motion tendency flowing from bottom to top but also kinetic energy of motion tendency flowing from outside to inside under the guidance of the inner side wall 11a of the first shell portion 11; secondly, the inner side wall 11a of the first shell part 11 is a plane wall, which is easy to form a stable flow; in addition, because the inner side wall 13a of the intermediate transition shell portion 13 is a circular arc wall, the inner side wall 11a of the first shell portion 11 and the inner side wall 12a of the second shell portion 12 are in smooth transition connection through the inner side wall 13a of the intermediate transition shell portion 13, so that at least part of gas can smoothly enter the second path segment 102 from the first path segment 101 under the guidance of the inner side wall 13a of the intermediate transition shell portion 13 on the flow path from the first path segment 101 to the intermediate path segment 103, and the defect that a large number of vortexes are formed in the intermediate path segment 103 is effectively improved. Because the inner side wall of the upper shell 1 has the structural improvement point, external air flow can enter the air passing channel 10 relatively more, so that more air flow can be supplemented into the cabinet inner cavity 3, and a large amount of vortex flow formed near the air outlet 15 is reduced.

The structural form of the inner side wall 12a of the second shell portion 12 can be various, and can be selected from the following three technical solutions according to actual needs: the first technical means of the second shell portion 12: as shown in fig. 4, the edge 22 of the supporting platform 2 is located at a height position shorter than that of the second shell portion 12, and the inner side wall 12a of the second shell portion 12 extends obliquely downward along the airflow direction so as to be capable of forcibly guiding at least a part of the airflow entering the second path segment 102 to flow downward from above and then to dive onto the supporting platform 2 through the air outlet 15. Thus, the amount of airflow blown out from the outlet 15 and blowing down from above and the impact force of the airflow can be relatively increased. The dive airflow can wash and clean harmful gas deposited on the table top of the support table 2 relatively strongly, and the harmful gas is pushed towards the inner direction of the cabinet inner cavity 3 by utilizing the plate surface flow guiding function of the support table 2 to be far away from the lower air supply device. Furthermore, the flowing range of the airflow can be expanded by utilizing the rebound effect of the table top of the support table 2 on the airflow, and harmful gas which drifts in a certain height range away from the table top of the support table 2 is pushed towards the inner direction of the cabinet inner cavity 3. It can be seen that the catching ability of the hood against harmful gas is effectively optimized and the amount of harmful gas leaking to the outside is reduced by the structure of the inner side wall 12a of the second shell portion 12 extending obliquely downward in the gas flow direction in a very compact structure. Further, a water blocking boss 21 extending in the direction x is provided on the support base 2, and a reference line a extending in the oblique direction of the inner side wall 12a of the second housing portion 12 enters an inner space of the water blocking boss 21. In this way, under the guidance of the inner side wall 12a of the second shell part 12, at least part of the airflow in the air passage 10 can go over the water-blocking boss 21 and enter the inner space of the water-blocking boss 21 to flush and push harmful gas deposited on the table top of the support table 2 in a manner of diving from top to bottom. In addition, the water blocking boss 21 can prevent liquid scattered on the support table 2 from dropping on the ground. In order to simplify the processing of the second shell portion 12 and optimize the smoothness of airflow in the air passing channel 10, the inner side wall 12a of the second shell portion 12 is a planar wall. Therefore, the impact force of the downward-rushing airflow can be strengthened, and the capability of catching harmful gases by the fume hood is further improved.

The other two technical solutions of the second shell portion 12 are respectively as follows: the inner side wall 12a of the second shell portion 12 extends obliquely upward in the air flow direction so that the air flow blown out from the air outlet 15 can be blown from below to above. Thus, even if the water blocking bosses 21 are higher than the inner side wall 12a of the second shell portion 12, the air flow blown out from the air passage 10 can still enter the vicinity area on the table top of the supporting table 2 under the guidance of the inner side wall 12a of the second shell portion 12. Or the inner side wall 12a of the second shell portion 12 extends horizontally so that the air flow blown out from the air outlet 15 can be blown horizontally.

As shown in FIG. 4, the exterior side wall 12b of the second shell portion 12 is a planar wall extending in an obliquely downward direction in the gas flow direction. In this way, a part of the external air is directed by the outer side wall 12b of the second housing portion 12 to dive from top to bottom onto the supporting platform 2 to form a second air flow, so as to be able to combine with the air flow blown out from the air outlet 15 and dive from top to bottom onto the supporting platform 2 to push the harmful gas deposited on the top of the supporting platform 2, thereby enhancing the cleaning capability of the harmful gas deposited on the top of the supporting platform 2. And the outer side wall 12b of the second shell part 12 is a plane wall, so that the impact force of the second path of airflow is strengthened, and the capability of catching harmful gases by the fume hood is further improved. In addition, the outer side wall 11b of the first shell portion 11 is a planar wall extending in an obliquely upward direction along the gas flow direction, the outer side wall 13b of the intermediate transition shell portion 13 is an arc wall, and the outer side wall 11b of the first shell portion 11 and the outer side wall 12b of the second shell portion 12 are joined in a smooth transition through the outer side wall 13b of the intermediate transition shell portion 13. Thus, a part of the outside air is blown from below to above under the guide of the outer side wall 11b of the first housing part 11, so that the harmful gas floating at a certain height from the top of the support base 2 can be pushed forward away from the lower air supplement. Accordingly, the external air flow can be divided into branch flows flowing upwards and downwards under the guidance of the outer side wall of the upper shell 1, and the cleaning range of the air flow on harmful gas is enlarged. In the present embodiment, in order to simplify the structure and manufacturing process of the upper case 1, the upper case 1 may be manufactured using a thin plate.

As shown in fig. 4, the upper housing 1 covers at least part of the edge 22 of the support platform 2, and the support platform 2 becomes at least part of the lower channel wall of the air passage 10. Thus, the lower air supplement structure of the fume hood is simplified. The upper casing 1 further includes a tail plate 16 connected to a lower end of the first casing 11, the tail plate 16 extends vertically, an air inlet 14 of the air passage 10 is formed between the tail plate 16 and an edge 22 of the support platform 2, and the air inlet 14 is communicated with an external space of the cabinet inner cavity 3. According to the technical scheme, the air inlet 14 is arranged downwards, and when an experimenter stands beside the lower air supplement device for an experiment, the air inlet 14 cannot be easily shielded by the body of the experimenter to damage the air supplement effect.

In order to reduce the formation of vortex in the air passage 10, as shown in fig. 9, the lower air compensator further includes air guide fins 17 extending along the flow path of the air compensation, and the air guide fins 17 are disposed in the air passage 10. In this way, the airflow in the air passage 10 is guided by the air guide fins 17, and the generation of a vortex is reduced. The air guide device further comprises a fin connecting piece 171, wherein one end of the fin connecting piece 171 is connected with the air guide fin 17, and the other end of the fin connecting piece 171 is connected with the upper shell 1. The air guide vane 17 and the vane connecting member 171 may be of a separate structure or an integral structure.

As shown in fig. 1, 8 and 9, the lower air supply device is disposed at a threshold position of the operation window 30 (the threshold position of the operation window 30 refers to a bottom position of the operation window 30), and the front end and the rear end of the air outlet 15 of the lower air supply device are respectively close to the left cavity side wall 31 and the right cavity side wall 32 of the cabinet inner cavity 3. The air outlet 15 includes a head-end air outlet expansion opening 151, a tail-end air outlet expansion opening 152, and a middle air outlet narrowing opening 153 located therebetween, and a height H2 of the head-end air outlet expansion opening 151 relative to the support table 2 and a height H3 of the tail-end air outlet expansion opening 152 relative to the support table 2 are respectively greater than a height H4 of the middle air outlet narrowing opening 153 relative to the support table 2. In the direction x, the width W1 of the head-end air outlet expansion 151 and the width W2 of the tail-end air outlet expansion 152 are smaller than the width W3 of the middle air outlet narrow opening 153. In this way, in the unit length range in the direction x, the flow rate of the air blown out from the head-end air-out expansion port 151 and the tail-end air-out expansion port 152 is greater than the flow rate of the air blown out from the middle air-out narrowing port 153, so that the air flow in the middle area is regulated by the strong air flows on both sides, the air flow blown out from the air outlet 15 flows smoothly and intensively as a whole, and the capability of the air flow to capture and clean the harmful gas in the area near the table top of the support table 2 is effectively improved. In addition, the flow range of the air flow blown out by the head-end air outlet expansion opening 151 and the tail-end air outlet expansion opening 152 relative to the middle air outlet narrowing opening 153 in the up-down direction is larger, and the flow rate is relatively more, so that the heavy molecular gas which stays at the corners of the two sides in the cabinet inner cavity 3 and is arranged at the head end and the tail end of the air outlet 15 can be blown away more quickly. The head-end air-out expansion opening 151 and the tail-end air-out expansion opening 152 can provide appropriate air volume for the gradually expanded overfire air opening 71 and the gradually expanded overfire air opening 71a, so that uniform surface air speed can be maintained.

Secondly, in the segment of supplementing wind through the operation window 30 in the fume hood, the related technical standards generally require that the operation window 30 has a uniform and stable surface wind speed (about 0.5 m/s). Since the central air outlet slot 153 corresponds approximately to the central region of the operating window 30, the central area of the operation window 30 has the largest amount of air supplied, and the head-end outlet expansion 151 and the tail-end outlet expansion 152 correspond to the left and right sides of the operation window 30, so that the left and right sides are relatively small with respect to the amount of air supplied to the central area of the operation window 30, in the above layout structure, the characteristics that the heights of the head-end air-out expansion opening 151 and the tail-end air-out expansion opening 152 relative to the support platform 2 are respectively greater than the heights of the middle air-out narrowing opening 153 relative to the support platform 2 can be further utilized to make up for the problem that the relative air supply at the left and right sides of the operation window 30 is insufficient and the air supply at the central area of the operation window 30 is excessive, so that the uniformity and stability of the air speed at the surface of the operation window 30 are greatly improved.

The head end and the tail end of the upper shell 1 are respectively close to a left cavity side wall 31 and a right cavity side wall 32 of the cabinet inner cavity 3. The lower air supplement device also comprises a plug 18 arranged at the head end of the upper shell 1 and a plug 18a arranged at the tail end of the upper shell 1. The plug 18a has a similar structure to the plug 18, and the plug 18 is described below for the purpose of example, and the plug 18 includes a plug main body 181 for plugging the end of the air passage 10 and a plug connecting portion 182 for fixing the plug main body 181 to the upper housing 1. A screw passes through the plug body 181 of the plug 18 to secure the plug 18 to the left chamber side wall 31 and a screw passes through the plug body of the plug 18a to secure the plug 18a to the right chamber side wall 32. In this way, the end of the air passage 10 can be blocked by the plug 18 and the plug 18a, and the lower air supplement device can be fixed. In addition, a movable cabinet door 4 is provided in the operation window 30, and the upper housing 1 can define the lowest limit position of the cabinet door 4, that is, the cabinet door 4 can be abutted against the upper housing 1 when it is dropped. In this way, when the door 4 completely closes the operating window 30, the air outside the cabinet interior 3 can still be guided through the air duct 10 to replenish the air in the vicinity of the top of the support table 2. In another embodiment, the air duct 10 of the present invention may be applied to a structure in which a blower is installed at an inlet thereof or a duct communicating with the inlet thereof, and the lower air supply unit may be directly connected to the support table 2.

Claims (14)

1. Fume chamber with mend wind structure is in including experimental brace table and the setting of using brace table top's cabinet inner chamber, its characterized in that: the air supply device also comprises a lower air supply device, the lower air supply device comprises an air passing channel which can circulate and supply air, an air outlet of the air passing channel extends along the edge direction x of the support platform, the air channel is used for supplying air from the outside of the cabinet inner cavity to the nearby area on the supporting platform surface, the lower air supplement device also comprises an upper shell which forms part of the channel wall body of the air passing channel and is positioned above the air passing channel, on the flow path of the supplementary air, the upper shell comprises a first shell part, an intermediate transition shell part and a second shell part which are arranged in sequence, so that the air passing channel is also divided into a first section, an intermediate section and a second section which correspond to the first shell part, the intermediate transition shell part and the second shell part and are communicated with each other, wherein the external air enters from the first road section and flows through the intermediate road section and then flows out from the second road section; viewed from a cross section direction perpendicular to the direction x, the inner side wall of the first shell part is a plane wall extending along the airflow direction in an inclined upward direction, the inner side wall of the intermediate transition shell part is an arc wall, and the inner side wall of the first shell part and the inner side wall of the second shell part are in smooth transition connection through the inner side wall of the intermediate transition shell part.

2. A fumehood with an air supplementing structure according to claim 1 wherein the edge of said support platform is at a lower height than the second shell portion, and the interior side wall of said second shell portion extends obliquely downwardly in the direction of airflow so as to be able to forcibly direct at least part of the airflow entering said second section to flow downwardly from above and then to dive into said support platform through said air outlet.

3. A fume chamber with an air supplement structure according to claim 2, wherein a water blocking boss extending in a direction x is provided on the supporting base, and a reference line extending in an oblique direction of an inner side wall of the second casing portion enters an inner space of the water blocking boss.

4. A fumehood with an air supplementing structure according to claim 2 wherein the interior side wall of said second shell portion is a planar wall.

5. The fumehood with air supplement structure of claim 1 wherein the inner side wall of said second housing portion extends obliquely upward in the direction of air flow so as to be able to guide at least a portion of the air flow blown out from said air outlet from below upward.

6. The fumehood with an air supplement structure of claim 1 wherein an interior side wall of said second housing portion extends horizontally to enable at least a portion of an airflow blown out from said air outlet to be directed horizontally.

7. A fumehood with an air supplement structure according to any one of claims 1 to 6 wherein the exterior side wall of the second shell portion is a planar wall extending in an obliquely downward direction along the direction of airflow.

8. A fume chamber with a wind supplementing structure according to claim 7, wherein the outer side wall of said first shell portion is a plane wall extending along the direction of air flow in an obliquely upward direction, the outer side wall of said intermediate transition shell portion is a circular arc wall, and the outer side wall of said first shell portion and the outer side wall of said second shell portion are joined in a smooth transition mode through the outer side wall of said intermediate transition shell portion.

9. A fumehood with an air supplementing structure according to any one of claims 1 to 6 wherein said upper housing covers at least part of the edge of said support platform and said support platform becomes at least part of the channel lower wall of said air over-flow channel.

10. The ventilated hood with air supplement structure according to claim 9, wherein the upper housing further comprises a tail plate joined to a lower end of the first housing portion, the tail plate vertically extends in an up-down direction, an air inlet of the air passing passage is formed between the tail plate and the edge of the supporting platform, and the air inlet communicates with an outer space of the inner cavity of the hood.

11. A fumehood with an air supplement structure according to any one of claims 1 to 6 wherein the chamber wall for constructing the inner chamber of said fumehood comprises a left chamber side wall, a right chamber side wall and a chamber back wall therebetween, said left and right chamber side walls being spaced apart from each other, and further comprising an operating window constructed opposite said chamber back wall, said operating window being adapted to form an access passage for performing an experiment on said support platform; the lower air supplement device is arranged at the lower threshold position of the door of the operation window, a movable cabinet door is arranged on the operation window, and the cabinet door is abutted to the upper shell when falling down.

12. The ventilated cabinet with the air supplement structure according to claim 11, wherein the head and the tail of the upper shell are respectively close to the left cavity side wall and the right cavity side wall of the inner cavity of the cabinet; the lower air compensating device further comprises plugs positioned at the head end and the tail end of the upper shell, the plugs comprise plug main bodies used for plugging the end parts of the air passing channels and plug connecting parts used for fixing the plug main bodies on the upper shell, and the plug main bodies of the plugs positioned at the head end and the tail end of the upper shell are respectively fixed on the left cavity side wall and the right cavity side wall.

13. A fumehood with an air supplement structure according to any one of claims 1 to 6 wherein said lower air supplement further comprises air guide fins extending along the flow path of the air supplement, said air guide fins being disposed within said air passing channel.

14. A fumehood with an air supplement structure as claimed in claim 13 further comprising a fin attachment member, one end of said fin attachment member being connected to said air guiding fin and the other end being connected to said upper housing.

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