EP3562600A1 - Laboratory fume hood having wall jets - Google Patents

Abstract

The invention relates to a fume hood (1) for a laboratory space, comprising a first hollow profiled element (10, 10'), which is arranged on a front-side end face of each side wall (36) and which has a first pressure chamber (10b, 10b') having a plurality of first openings (10d, 10d'), from which air jets in the form of wall jets (100) consisting of compressed air can be output along the associated side wall (36) into the working space. The size of the first openings (10d, 10d') and the air pressure present in the first pressure chamber (10b, 10b') are selected in such a way that the first pressure chamber (10b, 10b') can be fluidically connected to a building-installed compressed-air system (74) without the occurrence of flow separation of the wall jets (100) from the side wall (36) in a region from a front side of the working space to at least 25% of the depth of the working space. The invention further relates to a fume hood, wherein such a hollow profiled element (20, 20') is arranged on a front-side end face of the bottom plate (34).

Description

 Fume hood with wall jets

The present invention is concerned with a fume hood, in particular with a flow-optimized and energy-efficient fume hood.

Saving energy is not only environmentally friendly, but also reduces the sometimes very high operating costs of a modern laboratory room, which may contain dozens of fume hoods that operate 24 hours a day, 7 days a week. The most important feature of modern prints, however, is that they allow the safe handling of toxic substances and prevent the escape of these substances from the workspace of the trigger. The measure of this security is also referred to as retention. For this purpose, a detailed series of standards "EN 14175 Part 1 to Part 7" has been published describing, among other things, the influence of dynamic air flow on retention capacity Many developments in the field of fume cupboards therefore address the question of how the energy consumption of such fume cupboards is reduced without adversely affecting the retention capacity.

An attempt was made to improve the escape safety of fume hoods by means of an air curtain as early as the 1950s prevent toxic fumes from the working space (US 2 702 505 A).

It has been proposed in EP 0 486 971 A1 to provide so-called "air foils" at the front edge of the side posts and the front edge of the worktop whose flow-optimized contour is intended to be achieved by the teachings of EP 0 486 971 A1 open sash to less detachment of the incoming room air at the leading surface of the baffles and thus less swirling, but remains behind these baffles, an area in which there may be turbulence, as the incoming air at the downstream end of the baffles can be detached. Reinforced this effect occurs when room air enters the hood at an angle to the side walls. In GB 2 336 667 A, the retention capacity has been further improved by providing airfoil-shaped profiles at a distance from the front edge of the worktop and the side posts, so that room air can enter not only along the airfoil-shaped profiles in the draw-off interior, but also through the between Profiles and the front edge of the worktop on the one hand and the side post on the other hand existing, mostly funnel-shaped gap. The room air is accelerated in the funnel-shaped gap, so that the velocity profile of the exhaust air in the area of the side walls and the worktop is increased.

Another milestone to increase the outbreak safety while reducing the energy consumption of a fume hood was achieved by the optimized supply of so-called support jets. The fact that hollow sections are provided both on the front edge of the worktop and on the front end sides of the side posts, compressed air could be fed into the cavity of these profiles and blown through provided on the hollow sections openings in the form of compressed air jets in the working space. The advantage with this is that the compressed air jets along the sidewalls and along the worktop enter the workspace of the fume hood, ie along areas that are critical in terms of the risk of swirls (backflow areas) and therefore may adversely affect the retention capacity , The effect of compressed air jets in the area of the side walls and the floor of the working space is manifold. They not only prevent flow separations of the incoming room air at the downstream end of the hollow sections, but also reduce any wall friction effects, so that in these areas to significantly less turbulence and thus return flow areas can come. The room air entering the workspace glides on a dynamic, moving backwards air cushion along the walls and the worktop in the rear of the work space, where it is sucked out. At first glance, this seems contradictory, because the provision of compressed air jets costs additional energy. However, this has a positive effect on the overall energy balance of the fume cupboard since in the other areas of the fume cupboard the air speed can be reduced without adversely affecting the retention capacity. By means of these support jets, the minimum amount of exhaust air at which the escape-proof fume hood still complies with the standardized regulations could be lowered significantly with a partially opened or fully opened sash. An example of a fume hood equipped with a support jet technique is described in DE 101 46 000 AI, EP 1 444 057 Bl and US 9,266,154 B2. The inventors of the present invention were able to observe, for the first time in fume hoods equipped with conventional support jet technology, that in contrast to previously made investigations with nebulae where no significant flow separation of the wall beams could be observed, the flow field of the wall beams was examined by means of PIV measurements (Particle Image Velocimetry "measurements) flow separation is already a relatively short distance behind the level of the sash and therefore dangerous backflow areas on the side walls can arise.

Therefore, the main objective pursued by the present invention is primarily to further improve the break-out safety of a deduction equipped with a support jet technology while at the same time further reducing its energy consumption.

This object is solved by the features of claims 1 and 2. Optional or preferred features of the invention are indicated in the dependent claims.

Thus, the invention provides on the one hand a deduction for a laboratory space available, which has a housing in which there is a working space which is bounded on the front side by a sash, bottom side of a bottom plate and laterally each of a side wall. The trigger further comprises a first hollow profile disposed on a front end face of each side wall, each first hollow profile having a first pressure chamber fluidly connected to a plurality of first openings comprising air jets in the form of compressed air wall jets along the respective side wall the work space can be spent. The trigger is characterized in that the size of the first openings and the prevailing in the intended use of the trigger in the first pressure chamber air pressure are selected so that the first pressure chamber can be fluidly connected to a building side installed compressed air system, without causing a flow separation of the Wall blasting from the side wall in an area from a front of the working space to at least 25% of the depth of the working space comes.

On the other hand, the invention provides a fume hood for a laboratory space having a housing in which a working space is located, the front of a sash, bottom side of a bottom plate and laterally each of a side wall is limited. The trigger further comprises a second hollow profile disposed on a front end face of the bottom plate, the second hollow profile having a second pressure chamber fluidly connected to a plurality of second ports from which air jets in the form of compressed air ground jets along the bottom plate in the Work space can be spent. The trigger is characterized in that the size of the second openings and the pressure prevailing in the intended use of the trigger in the second pressure chamber air pressure are selected so that the second pressure chamber can be fluidly connected to a building side installed compressed air system, without causing a flow separation of the Ground jets from the bottom plate in an area from a front of the working space to at least 25% of the depth of the working space comes.

It is advantageous if the trigger has both a first hollow profile and a second hollow profile.

According to a preferred embodiment of the invention, there is no flow separation of the wall jets from the side wall or the bottom jets from the bottom plate in an area from the front of the working space to at least 50% of the depth of the working space.

And even more preferably, in the vent, there is no flow separation of the wall jets from the side wall or bottom jets from the bottom plate in an area from the front of the working space to at least 75% of the working space depth.

Likewise preferred are / is a first and / or a second pressure transducer is provided, which / are fluidly connected to the first and / or the second pressure chamber / is.

According to an advantageous embodiment of the invention, the first and / or the second pressure transducer comprises a first and / or a second pressure transducer arranged such that a pressure chamber side end of the first and / or the second pressure transducer line flush with an inner surface of the first and / or the second pressure chamber ends. It is also advantageous if a control device is provided which sets the pressure in the first and / or the second pressure chamber in the range of 50 Pa to 500 Pa, preferably in a range of 150 Pa to 200 Pa in the intended use of the trigger.

Preferably, the control device is electrically connected to the first and / or the second pressure accumulator.

It is even more preferable if the control device is a pressure reducer or a mass flow controller, which is arranged upstream of the first and / or the second pressure chamber.

According to a further preferred embodiment of the invention, the pressure reducer or the mass flow controller is disposed within the housing.

Preferably, a cross-sectional area, seen perpendicular to the flow direction, at least one of the first and / or the second openings, preferably of all first and / or second openings, in a range of 1 mm ² to 4 mm ² .

More preferably, a cross-sectional area, seen perpendicular to the flow direction, at least one of the first and / or the second openings, preferably all first and / or second openings, in a range of 1.8 mm ² to 3 mm ² .

An advantageous embodiment of the trigger is when at least one of the first and / or the second openings, preferably all first and / or second openings, is / are such that the first and / or the second opening leaving compressed air jet as periodic oscillating wall jet (100) and / or output as a periodically oscillating ground beam (200) in the working space.

It is also advantageous if the periodicity is in a range of 1 Hz to 100 kHz, preferably 200 Hz to 300 Hz.

According to yet another preferred embodiment of the invention, the periodic oscillation of the wall jet and / or the ground jet is merely non-movable Components of the first and / or the second hollow profile, which are preferably formed in one piece, generates.

It is even more preferable if the periodic oscillation of the wall jet and / or the ground jet is generated by self-excitation.

It is likewise advantageous if at least one first and / or one second fluidic oscillator is / is provided which comprises the first and / or second opening, preferably a multiplicity of first and / or second fluidic oscillators are provided, which respectively comprise a first and / or a second opening, and which generate / generate the periodic oscillation of the wall jet / wall jets and / or the periodic oscillation of the ground jet / ground jets.

It is even more preferable if the first and / or second openings have a circular, round, oval, right-angled or polygonal shape.

An advantageous embodiment of the invention relates to a trigger, which is characterized in that at least a first and / or a second opening via a first and / or a second elongated channel with the first and / or the second pressure chamber is fluidly connected, and that the first and / or the second channel has a length L which is at least 3 times, preferably 4 times to 11 times the hydraulic diameter of a cross-sectional area, seen perpendicular to the flow direction, the associated opening.

The invention will now be described purely by way of example with reference to the accompanying drawings. From the figures show

Fig. 1 is a perspective view of a conventional fume hood;

FIG. 2 is a cross-sectional view of the fume hood shown in FIG. 1 taken along the line A-A shown in FIG. 1; FIG.

Fig. 3, the supply of compressed air in the side post profiles and the

Baseplate profile; 4 shows a cross-sectional view of a hollow profile according to the invention, which is arranged on the front-side end side of the side wall and / or the front-side end side of the bottom plate;

5 shows a fluidic oscillator in the outlet channel of a hollow profile;

Fig. 6 shows the results of PIV measurements of the flow field of

 Wall blasting in a conventional fume hood (Figure 6A), in a fume hood with jet nozzles according to a preferred embodiment of the invention (Figure 6B) and in a fume hood with OsciJet nozzles according to another preferred embodiment of the invention (Figure 6C);

7 shows a test setup for determining the static air pressure in the

 Pressure chambers of the two side post profiles and the bottom profile;

8 shows a test setup for determining the volume flows of the

 Side post profiles exiting wall beams;

9 shows the measurement results of the static pressure in the pressure chambers of

 Side post profiles of a conventional fume hood (solid line), a fume hood with jet nozzles and OsciJet nozzles at different control voltages of the fan (dotted line and dashed line); and

10 is a diagram showing the reduction of the volume flows of the wall jets at different nozzle geometries of the side post profiles.

The fume hood 1 shown in perspective in FIG. 1 corresponds approximately to the fume hood, which is sold by the applicant since about 2002, almost worldwide under the name Secuflow ^®. Thanks to the support beam technology described above, this fume hood requires an exhaust air volume flow of only 270 m ³ / (h lfm). This deduction (Designation: Secuflow ^® TA-1500) served as a reference for the operations carried out under the present invention, measurements which are described further below.

The trigger according to the invention differs in particular with regard to the nozzle geometry of the hollow sections 10, 20 and the way in which the compressed air jets 100, 200 output from the hollow sections 10, 20 are produced, from the conventional Secuflow ^® trigger.

The fume hood 1 shown in Fig. 1 has a vent interior, the rear side preferably by a baffle 40, laterally by two side walls 36, bottom side by a bottom plate 34 or worktop, the front side by a closable sash 30 and ceiling side preferably limited by a ceiling panel 48 is.

The sash 30 is preferably designed in several parts such that a plurality of vertically displaceable window elements 30 extend in the same direction telescopically behind each other during opening and closing of the sash. The window element arranged furthest down in the closed position of the sash 30 preferably has an aerodynamically optimized airfoil profile 32 (FIG. 2) on its front edge. In addition, the sash 30 preferably has horizontally displaceable window elements which, even in the closed position of the sash 30, allow the laboratory personnel access to the withdrawal interior.

At this point it should be noted that the sash 30 may also be formed as a two-part sliding window, the two parts can be moved in opposite directions in the vertical direction. In this case, the opposing parts are coupled via ropes or belts and pulleys with the mass of the sash balancing weights.

Preferably located between the baffle 40 and the rear wall 62 (Fig. 2) of the trigger housing 60, a channel 63, which leads to a Abluftsammelkanal 50 on the top of the fume hood 1. The exhaust air collection channel 50 is connected to a building side installed exhaust device. Below the worktop 34 of the deduction interior furniture 38 is arranged, which serves as a storage space for different laboratory utensils. This For the purposes of the terminology used here, furniture is to be understood as part of the housing 60 of the fume hood 100.

At the front end sides of the side walls 36 of the fume hood 1, which are also commonly referred to as side posts, hollow sections 10 are provided. Likewise, a hollow profile 20 is provided on the front end side of the bottom plate 34.

If the term "on the front side" is used, this term is not to be understood literally, but rather also to designations that are provided or mounted only in the area of the front side.

Similar to the aerodynamically optimized airfoil profile 32 on the underside of the lowermost sash element 30, the airfoil-shaped inflow side 10a of the hollow profile 10 or of the side mullion profile 10 (FIG. 4) is preferably aerodynamically optimized. The same applies preferably to the hollow section 20 on the front end side of the bottom plate 34. The wing-like profile geometry allows a low-turbulence, in the optimal case even a turbulence-free inflow of room air in the vent interior with partially or fully open sash 30th

With the aid of the hollow profiles 10, 20, so-called support jets, i.e. compressed air jets 100, 200 made of compressed air, are introduced along the side walls 36 and the bottom plate 34 into the take-off interior. These compressed air jets are conventionally generated by a fan 70 (FIG. 3) arranged below the work surface 34 and inside the housing 60. Although in Fig. 2, the exact arrangement of the hollow sections 10, 20 is difficult to see, the hollow sections 10, 20 are preferably in front of the plane of the front sash member. The compressed air jets 100, 200 therefore preferably reach the discharge interior only when the sash 30 is partially or fully opened.

The fume hood 1 shown in Fig. 1 is purely exemplary to see because the invention can be applied to different types of fume cupboards, for example, table deductions, low-capacity table deductions, drawdowns, walk-in prints or even mobile fume hoods. Likewise, these deductions fulfill the valid on the filing date of the present patent application European standard series DIN EN 14175. Furthermore, the deductions can also meet other standards, such as the ASHRAE 110/1995, which is valid for the United States. If reference should be made to a standard in this description and the patent claims, the currently valid standard is always meant here. This is because, according to experience, the regulations specified in the standards are becoming ever stricter, and thus a trigger that meets the current standard also meets the requirements of an older standard.

2 greatly simplifies the flow pattern of the compressed air jets 100, 200 emerging from the hollow sections 10, 20 within the withdrawal interior and the exhaust air in the channel 63 between the baffle 40 and the rear wall 62 for the exhaust collection channel 50. The view in FIG. 2 corresponds a cross-sectional view along the line AA in Fig. 1st

As can be seen in Fig. 2, the baffle 40 is preferably spaced on the bottom side of the work surface 34 and preferably from the rear wall 62 of the housing, whereby the exhaust duct 63 is formed. The baffle 40 preferably has a multiplicity of elongate openings 42 (FIG. 1) through which the exhaust air or the air which is located in the withdrawal interior and possibly under toxic loading flows through and can enter the channel 63. On the ceiling 48 in the drawing-off interior, further openings 47 are preferably provided, through which, in particular, light gases and vapors can be conducted to the exhaust collecting channel 50.

Although not shown in FIGS. 1 and 2, the baffle 40 may also preferably be spaced from the side walls 36 of the trigger housing 60. Through a gap formed in this way, exhaust air can additionally be introduced through it into the exhaust air duct 63.

On the baffle 40, a plurality of tripod holders 44 are preferably provided, can be releasably clamped in the rods, which serve as supports for experimental setups in the deduction interior.

As shown in FIG. 3, in the conventional fume hood shown in FIGS. 1 and 2, the compressed air jets 100, 200 are generated by a fan 70 disposed below the bottom plate 34 and preferably within the housing 60. The fan 70 used in the measurements made in the invention was one one-sided sucking centrifugal fan from ebm Papst with the designation G1G097-AA05- 01.

The compressed air generated by the fan 70 is first fed into the arranged in the region of the front end side of the bottom plate 34 hollow section 20. The feeding of the fan pressure air into the hollow profile 20 preferably takes place at a location which is approximately in the middle of the longitudinal extension of the hollow profile 20 extending in the width direction of the trigger. In this way it is achieved that the pressure drop in the hollow profile 20 is approximately symmetrical relative to this point.

In Fig. 3 it can also be seen that the hollow profiles 10, 20 fluidly connected to each other. As a result, a portion of the compressed air reaches the two side post profiles 10 and exits from the side post profiles 10 in the form of support beams 100 along the side walls 36 in the withdrawal interior.

Although one would initially suspect that the energy demand of the fan 70 degrade the overall energy balance of the fume hood rather than would improve the applicant 200 of the minimum required to maintain the normalized breakouts exhaust air flow could, in the conventional fume hood Secuflow ^® due to the positive effect of the support beams 100, , ie the minimum volume flow that still meets the legal requirements for the breakout security of the trigger and that must be able to generate the exhaust air system installed on the building side and connected to the exhaust air collection duct 50. As a result, the energy requirement of the fume hood could be reduced by a level that exceeds the energy requirement of the fan, which in turn has a positive effect on the overall energy balance of the fume hood.

In Fig. 4, the structure and the geometry of a formed according to an embodiment of the invention hollow profile 10, 20 in cross-section, that is, shown perpendicular to the longitudinal extent of the Hohlpro fils 10, 20. The outer inflow side 10a, 20a is aerodynamically optimized designed as a wing profile. Inside the hollow profile 10, 20 is a pressure chamber 10b, 20b. Through the pressure chamber 10b, 20b, the compressed air generated by the fan 70 flows along the longitudinal extent of the hollow profile 10, 20. Also along the longitudinal extent of the hollow profile 10, 20 are preferably a plurality of outlet openings 10d, 20d, escape through which the compressed air in the discharge interior can. The multiplicity of spatially separated outlet openings 10d, 20d are arranged in the hollow profile 10, 20 corresponding to the respective point of use of the fume hood 1. They can be distributed irregularly over the length of the hollow profile 10, 20 or arranged according to a certain pattern or even equidistant and regular to each other.

The hollow profiles 10, 20 may preferably be formed integrally with the respective side wall 36 and / or the bottom plate 34, e.g. as extruded aluminum profile. Likewise, it is conceivable aufzustecken and fix the hollow sections 10, 20 on the end face of the respective side wall 36 and / or the bottom plate 34, or otherwise secure it.

Likewise, the plurality of outlet openings 10d, 20d - with or without outlet channel 10c, 20c - in the form of a profile strip in the respective hollow section 10, 20 introduced or integrally formed therewith.

The geometry shown in FIG. 4 is applicable both to the side post hollow profiles 10 and to the hollow profile 20 arranged on the front end side of the work plate or bottom plate 34. For better distinctness, in this description and in the patent claims, in part the side post profile is referred to as the first hollow profile 10 and the bottom plate profile as the second hollow profile 20.

In order to be able to compare various fluid-dynamic channels with different cross-sectional shape, which are traversed by a fluid, the so-called hydraulic diameter is used. The term "hydraulic diameter" is well known to the person skilled in the art and represents an arithmetic variable which indicates the diameter of a flow channel with an arbitrary cross-section, which has the same pressure loss at the same length and same average flow velocity as a flow tube with a circular cross-section and same diameter.

In the conventional fume hood Secuflow ^® by the applicant is the longitudinal dimension of the outlet openings 10d, 20d, ie, the extension of the outlet openings 10d, 20d perpendicular to the longitudinal direction of the hollow sections 10, 20 equal to 30 mm and the transverse dimension to equal to 2 mm. For a rectangular outlet opening, the hydraulic diameter is calculated according to the formula dh = 2ab / (a + b). If a = 30mm and b = 2mm, then the hydraulic diameter of each outlet opening 10d, 20d in the conventional Secuflow ^® fume hood is 3.75 mm and the surface area is 60 mm ² .

In the case of the hollow profiles 10, 20 according to a preferred embodiment of the invention shown in FIG. 4, the surface area of the outlet openings 10d, 20d is preferably only 1 mm ² to 4 mm ² , and more preferably 1.8 mm ² to 3 mm ² . The outlet openings 10d, 20d may preferably have a circular, round, oval, rectangular or polygonal shape.

The longitudinal extent of the nearly rectangular outlet openings 10d, 20d is preferably 3 mm and the transverse dimension perpendicular thereto is preferably 1 mm. This results in a hydraulic diameter of 1.5 mm. A hollow profile 10, 20 with outlet openings 10d, 20d formed in this way was also used in the measurement series carried out within the scope of the invention. Hereinafter, this hollow section 10, 20 is also referred to by the term "jet nozzles".

According to another aspect of the invention, at least one outlet opening 10d, 20d, preferably all outlet openings 10d, 20d provided in the hollow profile 10, 20 are fluidly connected to the pressure chamber 10b, 20b via a channel 10c, 20c having a length L (Fig. 4).

In the hollow section 10a, 20a shown in Fig. 4, the length L of the channel is preferably 9 mm. The ratio of the length L to the hydraulic diameter (1.5 mm) is thus equal to 6.

The measurement series carried out in the context of the invention suggest that the channel 10c, 20c, which is connected fluidly to preferably one outlet opening 10d, 20d, should have a length L which is at least 3 times, preferably 4 times to 11 times the hydraulic diameter of the outlet opening 10d, 20d is. Only at a channel length L, which meets this condition, compressed air jets are issued into the deduction interior, which a direction "mitgegeben" is given, which is much more pronounced than air jets that only have to go through a shorter channel Opening angle of the compressed air jets 100, 200 propagating in the drawing-off interior. In other words, the compressed-air jets 100, 200 are directed so strongly already at the time of leaving the outlet openings 10d, 20d that they bear as close as possible to the side walls 36 and the bottom plate 34.

In contrast, had used in the conventional fume hood Secuflow ^® and extruded aluminum hollow profile 10, 20 has a thickness of 2 mm, ie, the channel in front of the outlet opening had a length L of only 2 mm. The ratio of the length L to the hydraulic diameter (3.75 mm) was thus significantly smaller than 1.

The angle α (FIG. 4), which the preferably rectilinearly extending channel 10c, 20c encloses relative to the side wall 36 and / or the bottom plate 34, is preferably in a range of 0 ° to 10 °. It should be noted at this point that an air jet passing through a channel that encloses an angle of 0 ° to the associated side wall or base plate will not propagate absolutely parallel to the side wall or base plate in the drawing room interior. This is due to the fact that the mean velocity vector will always occupy an angle of greater than 0 ° to the side wall 36 or the bottom plate 34 even with parallel purging.

According to a further preferred embodiment of the invention, instead of a straight line from the pressure chamber 10b, 20b to the outlet 10d, 20d extending channel 10c, 20c (Fig. 4), an outlet geometry shown in Fig. 5 is provided, which is the blowing of a preferably periodically oscillating compressed air jet allows. This nozzle geometry is also referred to below as OsciJet.

In this context, it is pointed out that the detail shown in FIG. 5 corresponds approximately to the partial region indicated by dashed lines in FIG. 4, so that the remaining features of the hollow profiles 10, 20 which were explained in connection with FIG. 4 also on the hollow sections 10 ', 20' of Fig. 5 are transferable.

The periodic oscillation is preferably generated by self-excitation and preferably by means of non-movable components, which are preferably formed integrally with the hollow profile 10 ', 20'. For this purpose measurements were carried out within the scope of the invention with the aid of so-called fluidic oscillators. Fluidic oscillators are characterized by producing a self-excited vibration in the fluid passing therethrough. This vibration results from dividing the fluid stream into a skin stream and a partial stream. While the main flow is flowing through a main passage 10c ', 20c', the sub-flow flows alternately through one of the two sub-passages 10f, 20f (Fig. 5). In the region of the outlet opening 10d ', 20d', the partial stream again meets the main stream and deflects it alternately downwards or upwards, depending on which secondary channel 10f, 20f the partial stream had previously passed through. Due to the alternately changing pressure conditions in the secondary channels 10f, 20f, the partial flow in the next cycle flows through the respective other secondary channel 10f, 20f. This results in a deflection of the main and partial flow in the other direction in the region of the outlet opening 10d ', 20d'. Then the processes repeat themselves.

Also in the nozzle geometry of Fig. 5, the outlet port 10d ', 20d' is fluidly connected to a pressure chamber 10b ', 20b' via a passage 10c ', 20c' (here, the main passage) having a length L. Again, the channel length L is at least 3 times, preferably 4 times to 11 times the hydraulic diameter of the outlet 10d ', 20d'. In a preferred embodiment of the invention, the longitudinal extension of the substantially rectangular outlet opening 10d ', 20d' is equal to 1.8 mm and the extension perpendicular thereto equal to 1 mm. This results in a hydraulic diameter of 1.3 mm. The channel length L is preferably 14 mm and thus about 11 times the hydraulic diameter.

As an alternative to the OsciJet nozzle geometry, nozzle geometries are also conceivable which generate a nonperiodic compressed air jet. In other words, such nozzle geometries create a reciprocating, stochastically moving compressed air jet. To produce such non-periodic compressed air jets, unlike fluidic oscillators, feedback-free fluidic components may be used.

Fig. 6 shows the result of PIV measurements of the flow field of the wall beams output from the side of the post section 10 by using the conventional nozzle geometry of Secuflow ^® trigger (Fig. 6A) jet nozzle geometry (Fig. 6B) and the OsciJet nozzle geometry (Fig 6C). The fan voltage was 9.85V in the measurements shown in FIG. In Fig. 6a can be clearly seen how the air flowing through the open sash room air despite blowing of support beams 100 from the hollow section 10 is detached after about 150 mm behind the front sash, which corresponds to the 0-position of the side wall. This detachment was not observed in previous fog examinations. Such a detachment can not be seen in FIGS. 6b and 6c. In FIG. 6B and FIG. 6C, the room air flows along the side wall without turbulences and the formation of backflow areas. Also, the field line density, which indicates higher air velocities, is significantly higher in the region of the side wall in FIG. 6B and in FIG. 6C than in FIG. 6A. From this and the OsciJet nozzle geometry can be concluded that the ambient air in the case of jet nozzle geometry (Fig. 6B) (Fig. 6C) significantly faster flows toward the baffle wall of the hood inner space than in the case of the conventional nozzle geometry of Secuflow ^® trigger (Fig. 6A). Likewise, it can be seen in FIG. 6B and FIG. 6C how the room air itself extends at a distance from the side-post profile 10, 10 '(y-axis) towards the side wall, while in FIG. 6A the room air tends to be more of the side wall flows away.

The PIV measurements of the flow field thus show very clearly that flow separations can be effectively prevented in both the jet nozzle (FIG. 4) and in the OsciJet nozzle (FIG. 5). In addition, the incoming air in the front, wing-shaped area of the side post is better at, whereby the risk of backflow is further reduced.

A series of PIV measurements were made at different control voltages of the fan 70 (Figure 3). In this case, a higher control voltage corresponds to a higher blow-out speed of the support beams. The PIV measurements made it clear that the goal of avoiding flow separation is better achieved at higher jet speeds. To realize this aspect of the invention, it is sufficient if flow separation in a region from the front of the working space to at least 25% of the depth of the working space is avoided. This corresponds to the area of the working area which is to be assessed particularly critically with regard to dangerous backflow areas. Preferably, this value is at least 50%, and more preferably 75%. After the control voltage of the fan 70 was determined experimentally, in which a virtually turbulence-free course of the flow could be found without significant backflow areas, the inventors have the question of what minimum volume flow is necessary to reproduce a turbulence-free flow field can.

Due to the small dimensions of the Jet and OsciJet Düsenauslassöff openings 10d, 20d and 10d ', 20d' provides a measurement of the air outlet velocity with the aid of a Hitzdrahtaneometers no reproducible results. In the case of the OsciJet nozzles, the hot-wire ananometer oscillates even with the periodically oscillating support beams.

According to a further aspect of the invention, a method for determining the minimum volume flows was then developed. The associated experimental setup is shown in FIGS. 7 and 8 shown.

The determination of the volume flow of the wall beams takes place in two steps. As shown in Fig. 7, by means of a voltage regulator 72, the control voltage of the fan 70 is set to a value at which the flow field of the wall jets verified by means of PIV measurements shows almost no significant flow separations. At the measuring points 1, 2, 3, 4, 5 and 6, the static pressure within the hollow sections 10, 10 'and 20, 20' is subsequently determined. For this purpose, a pressure transducer 80 is used which preferably measures the static pressure in the pressure chambers 10a, 10a 'and 20a, 20a' of the hollow profiles 10, 10 'and 20, 20' via respective pressure transducer lines 82. The pressure transducer lines 82 are preferably arranged so that their pressure-chamber-side end surface flush on an inner surface of the respective pressure chamber 10a, 10a 'and 20a, 20a' ends. In this first measurement step, only a hollow profile 10 with jet nozzles is used by way of example on the left side post, and a hollow profile 10 'with OsciJet nozzles is used on the right side post.

In a second measuring step, as can be seen in FIG. 8, the fan 70 is replaced by a compressed air connection 74. Downstream of the compressed air port 74, a calibrated pressure reducer or mass flow controller 76 is placed. The mass flow controller used here was from the company Teledyne Hastings Instruments, Series 201. After setting the static reference air pressure determined in the first measuring step in the Hollow profiles 10, 10 'and 20, 20' can be determined with the help of the mass flow controller of the associated mass flow. Taking into account the ambient pressure and the ambient temperature, the volumetric flow can be calculated from the respective mass flow.

FIG. 9 shows the measured static air pressures in the pressure chambers 10a, 10a 'of the hollow profiles 10, 10'. The lowest solid line is presented merely for purposes of comparison and shows the static air pressure in the hollow profile of the series trigger Secuflow ^®, namely at a fan voltage of 4.41 V. The average static air pressure here is 12.5 Pa. The dotted line indicates an average value of 65 Pa and was determined for the Jet and OsciJet nozzles at a fan voltage of 4.41V. The top dashed line corresponds to an average air pressure of 197 Pa. This was determined at a fan voltage of 9.85 V using the Jet and OsciJet nozzles. At this point it should be noted that the series ^® within the profile of the trigger Secuflow are not shown at a fan voltage of 9.85 V measured average static air pressures in Fig. 9.

The resulting volume flows are shown in FIG. 10. With the optimized jet jet nozzles Jet and OsciJet, the required minimum volume flow is reduced by 68% in the Jet version and by 76% in the OsciJet version compared to the Secuflow ^® standard drawing.

According to another aspect of the invention, the inventors have concluded that due to the greatly reduced volume flow rates it is now possible to provide a full fume hood, i. H. To operate a laboratory fume hood, which complies with the DIN EN 14175 series of standards, in accordance with the requirements of a building-standard compressed-air system. The person skilled in the art is aware at this point that such compressed air systems installed on the building side can usually provide an air pressure in a range of 0 to 7 bar. A power-driven fan is unnecessary.

Not all outlet openings 10d, 10d 'of the side-post profile 10, 10' and not all outlet openings 20d, 20d 'of the bottom plate profile 20, 20', which are intended for the output of wall jets 100 or ground jets 200 in the respective hollow profile 10, 20 According to the invention, they must have the nozzle geometry shown in FIG. 4 or FIG. 5 in order to realize the subject matter specified in the patent claims. It is therefore sufficient that at least one outlet opening 10d, 10d 'of the side-post profile 10, 10' and / or at least one outlet opening 20d, 20d 'of the bottom-plate profile 20, 20' is / are formed in this way. The same applies to the length L of the channel 10c, 10c 'and 20c, 20c', which is provided immediately upstream of the respective outlet opening 10d, 10d 'and 20d, 20d'.

Claims

claims

1. hood (1) for a laboratory, comprising a housing (60) in which there is a working space, the front of a sash (30), bottom of a bottom plate (34) and laterally bounded by a side wall (36) and a first hollow profile (10, 10 ') disposed on a front end face of each side wall (36), each first hollow profile (10, 10') having a first pressure chamber (10b, 10b ') fluidly communicating with a plurality of first openings (10d, 10d ') is connected, from which air jets in the form of compressed air wall jambs (100) along the respective side wall (36) can be output in the working space,

 characterized in that the size of the first openings (10d, 10d ') and the prevailing in the intended use of the trigger in the first pressure chamber (10b, 10b') prevailing air pressure are selected so that the first pressure chamber (10b, 10b ') with a building-side installed compressed air system (74) can be fluidly connected, without causing a flow separation of the wall jets (100) from the side wall (36) in an area from a front of the working space to at least 25% of the depth of the working space.

2. hood (1) for a laboratory, comprising a housing (60) in which a working space (3) is located, the front side of a sash (30), bottom side of a bottom plate (34) and laterally each of a side wall ( 36) is limited, and arranged on a front end side of the bottom plate (34) second hollow section (20, 20 '), wherein the second hollow profile (20, 20') has a second pressure chamber (20b, 20b ') fluidly with a plurality of second openings (20d, 20d ') is connected, from which air jets in the form of compressed air existing ground jets (200) along the bottom plate (34) can be output in the working space,

characterized in that the size of the second openings (20d, 20d ') and the prevailing in the intended use of the trigger in the second pressure chamber (20b, 20b') prevailing air pressure are selected so that the second pressure chamber (20b, 20b ') with a building-side installed compressed air system (74) can be fluidly connected without causing a flow separation of the ground jets (200) from the bottom plate (34) in an area from a front of the working space to at least 25% of the depth of the working space.

3. trigger (1) having the features of claims 1 and 2.

4. trigger (1) according to any one of the preceding claims, characterized in that there is no flow separation of the wall jets (100) of the side wall (36) or the ground jets (200) of the bottom plate (34) in an area from the front of the Working space up to at least 50% of the depth of the working space comes.

5. trigger (1) according to any one of the preceding claims, characterized in that there is no flow separation of the wall jets (100) of the side wall (36) or the ground jets (200) of the bottom plate (34) in an area from the front of the Working space up to at least 75% of the depth of the working space comes.

6. trigger (1) according to any one of the preceding claims, characterized in that a first and / or a second Druckaumehmer (80) are / is provided, the / the fluidly with the first (10b, 10b ') and / or the second (20b, 20b) pressure chamber are connected / is.

7. trigger (1) according to claim 6, characterized in that the first and / or the second Druckaumehmer (80) comprises a first and / or a second pressure transducer line (82) arranged / is such that a pressure chamber side end of first and / or the second pressure transducer line (82) ends flush with the surface on an inner surface of the first (10b, 10b ') and / or the second (20b, 20b') pressure chamber.

8. trigger (1) according to any one of the preceding claims, characterized in that a control device (76) is provided, the pressure in the first (10b, 10b ') and / or the second (20b, 20b ') Pressure chamber in a range of 50 Pa to 500 Pa, preferably in a range of 150 Pa to 200 Pa sets.

9. trigger (1) according to claim 8, as far as it is dependent on one of claims 6 or 7, characterized in that the control device (76) with the first and / or the second pressure transducer (80) is electrically connected.

10. trigger (1) according to claim 8 or 9, characterized in that the control device is a pressure reducer or a mass flow controller (76) upstream of the first (10b, 10b ') and / or the second (20b, 20b') pressure chamber is arranged.

11. trigger (1) according to claim 10, characterized in that the pressure reducer or the mass flow controller (76) within the housing (60) is arranged.

12. trigger (1) according to any one of the preceding claims, characterized in that a cross-sectional area, viewed perpendicular to the flow direction, at least one of the first (10d, 10d ') and / or the second (20d, 20d') openings, preferably all first and / or second openings, in a range of 1 mm ² to 4 mm ² .

13. trigger (1) according to any one of the preceding claims, characterized in that a cross-sectional area, viewed perpendicular to the flow direction, at least one of the first (10d, 10d ') and / or the second (20d, 20d') openings, preferably all first and / or second openings (10d, 10d ') is in a range of 1.8 mm ² to 3 mm ² .

14. trigger (1) according to any one of the preceding claims, characterized in that at least one of the first (10d, 10d ') and / or the second (20d, 20d') openings, preferably all first and / or second openings, formed is / are that the first (10d, 10d ') and / or the second (20d, 20d') leaving the compressed air jet output as a periodically oscillating wall jet (100) and / or as a periodically oscillating ground jet (200) in the working space ,

15. trigger (1) according to claim 14, that the periodicity in a range of 1 Hz to 100 kHz, preferably white 200 Hz to 300 Hz.

16. trigger (1) according to any one of claims 14 or 15, characterized in that the periodic oscillation of the wall jet (100) and / or the ground jet (200) by only non-movable components of the first (10) and / or the second (20) hollow profiles, which are preferably formed in one piece, is generated.

17. trigger (1) according to one of claims 14 to 16, characterized in that the periodic oscillation of the wall jet (100) and / or the ground jet (200) is generated by self-excitation.

18. trigger (1) according to one of claims 14 to 17, characterized in that at least one first and / or a second fluidic oscillator (11) are / is provided, the / the first (10d ') and / or the second (20d ') opening comprise / include, preferably a plurality of first and / or second fluidic oscillators are provided, each comprising a first and / or a second opening, and the / the periodic oscillation of the wall beam / wall jets (100) and / or generate / generate the periodic oscillation of the soil jet (s) (200).

19. trigger (1) according to any one of the preceding claims, characterized in that the first (10d, 10d ') and / or second (20d, 20d') openings have a circular, round, oval, rectangular or polygonal shape.

20. trigger (1) according to any one of the preceding claims, characterized in that at least one first (10d, 10d ') and / or a second (20d, 20d') opening via a first (10c, 10c ') and / or a second (20c, 20c ') elongated channel to the first (10b, 10b') and / or the second (20b, 20b ') pressure chamber is fluidly connected, and that the first (10c, 10c') and / or the second ( 20c, 20c ') channel has a length L which is at least 3 times the hydraulic diameter of a cross-sectional area, viewed perpendicular to the flow direction, of the associated opening.