EP3773983A1

EP3773983A1 - Ventilation device for filtering air and for separating water aerosols out of the air

Info

Publication number: EP3773983A1
Application number: EP19702220.5A
Authority: EP
Inventors: Steffen Gorzawski; Wolfgang Kugel; Andreas SZONTKOWSKI; Fritz RÖDIGER
Original assignee: Filtration Group GmbH
Current assignee: Filtration Group GmbH
Priority date: 2018-03-27
Filing date: 2019-01-23
Publication date: 2021-02-17
Also published as: DE102018204632B4; DE102018204632A1; US20210039027A1; WO2019185212A1; CN112088040A

Abstract

The invention relates to a ventilation device (1) for filtering air and for separating water aerosols out of the air. The ventilation device (1) has at least one filter element (3), at least one housing (4), at least one fan (5), and at least one flow adapter (11). The at least one filter element (3) is secured in the at least one housing (4) such that air can flow through the filter element from an inlet opening (8) to an outlet opening (9) of the at least one housing (4) in a flow direction (10). In the flow direction (10), the at least one fan (5) is secured to the outlet opening (9) downstream of the at least one housing (4) and the at least one flow adapter (11) is secured to the inlet opening (8) upstream of the at least one housing (4). A coupling frame (14) is secured in an airtight manner between the at least one housing (4) and the at least one flow adapter (11) transversely to the flow direction (10). According to the invention, the at least one filter element (3) has a circumferential seal edge (23), wherein the seal edge (23) rests against a seal surface (24) of the at least one housing (4) on one side, said seal surface bordering the inlet opening (8), and against the coupling frame (14) on the other side and seals the at least one housing (4) to the coupling frame (14) around the inlet opening (8) transversely to the flow direction (10).

Description

Ventilation device for filtering air and separating water aerosols from air

The invention relates to a ventilation device for filtering air and for separating water aerosols from air according to the preamble of claim 1.

Ventilation devices for filtering air and for separating water aerosols from air are already known from the prior art and are used, for example, in wind power plants. Depending on the location of the wind turbine, the air drawn in from outside must be cleaned and dewatered to protect electronic or electrical components inside the wind turbine. To do this, blowers suck in the air into the wind turbine through filter elements in which the sucked air is cleaned and dewatered. However, the not yet cleaned and dewatered air must not escape from the ventilation device before cleaning and draining through the respective filter element. For this purpose, the ventilation system is sealed to the outside by at least one seal, which must regularly renewed or replaced time-consuming and power-consuming.

The object of the invention is therefore to provide an improved or at least alternative embodiment for a ventilation device of the generic type, in which the described disadvantages are overcome.

This object is achieved by the subject of independent claim 1. Advantageous embodiments are the subject of the dependent claims. The present invention is based on the general idea of performing a first or a new sealing in a ventilation system for filtering air and separating water aerosols from air when inserting or replacing the respective filter element. The generic ventilation device has at least one filter element, at least one housing, at least one fan and at least one flow adapter.

The at least one filter element in the at least one housing is fixed in an air flow direction from an inlet opening to an outlet opening of the respective housing in a direction of flow. The at least one fan is at the outlet opening in the flow direction behind the respective housing and the at least one flow adapter is fixed at the inlet opening in the flow direction in front of the at least one housing. Furthermore, a coupling frame between the at least one housing and the at least one flow adapter is fixed airtight transversely to the flow direction. According to the invention, the at least one filter element has a circumferential sealing edge, wherein the sealing edge abuts on one side on a sealing surface of the at least one housing which surrounds the inlet opening and on the coupling frame on the other side and which seals at least one housing around the inlet opening to the coupling frame transversely to the flow direction , The sealing edge seals a pressure chamber of the ventilation device and is arranged on the filter element, so that when inserting or replacing the at least one filter element in the ventilation device and the sealing edge can be used or replaced. In particular, the sealing of the pressure chamber of the ventilation device can be made without tools by the sealing edge and thereby the time and effort are reduced during the first and when re-sealing the ventilation device.

The sealing surface may be formed by a housing frame enclosing the inlet opening, which has a radially inwardly projecting inlet step in FIG forms the respective housing. In this advantageous manner, the air flow can be conducted without losses to the filter element in the respective housing. Advantageously, it may be provided that an elastic seal is fixed to a side surface of the sealing edge facing the housing and / or the coupling frame. The elastic seal can be firmly bonded to the side surfaces of the sealing edge - for example, glued - or, however, non-positively locked - for example, in a profile groove - fixed.

In the aeration device, the at least one flow adapter, the at least one housing with the at least one filter element and the at least one fan in the flow direction are connected successively, so that the air through the at least one flow adapter to the inlet opening of the at least one housing and on through which at least one filter element can flow. In this case, the air can be sucked in from the outside by the blower and can be conducted further into the housing with the filter element by the at least one flow adapter. The housing can advantageously be made of plastic - for example, rotationally molded - be. The flow adapter can advantageously be flow-optimized and the geometry of the flow adapter can be adapted to the particular application. The filter element has purportedly a clean and a raw side and is formed from a filter material. In this case, the filter material can be, for example, hydrophobic and the water in the intake air can be deposited in a filtration zone. The separated in the filter element water can then settle on the raw side of the filter element under the action of gravity in a drainage zone of the filter element. The drainage zone adjoins the filtration zone of the filter element and is expediently arranged offset transversely to the flow direction below the filtration zone of the filter element. The filtration zone of the filter element corresponds to a Filtrierbereich and the drainage zone with a drip area of the housing. The filtration area and the drip area of the housing in this case close to each other.

In an advantageous development of the ventilation device according to the invention, it is provided that the at least one flow adapter is in one piece and preferably made of plastic. The flow adapter is consequently of robust construction, so that the air sucked in from outside by the at least one fan can already be distributed in the flow adapter and can flow uniformly over the filter element. In particular, the respective filter element can be spared and used longer. Furthermore, the flow adapter made of plastic advantageously only slightly increases the dead weight of the ventilation system. The at least one flow adapter can have a collecting region and a flow region which adjoin one another. The flow region of the flow adapter corresponds in this case to the inlet opening of the housing in an air-conducting manner, and the collecting region is arranged offset transversely to the direction of flow below the flow region. Furthermore, the collecting area lies outside a main air flow of the flow adapter. In the ventilation device, the flow region of the at least one flow adapter corresponds to the filtration region of the respective housing and the filtration zone of the respective filter element in the housing. By contrast, the collecting region lies offset transversely to the flow direction below the flow region of the flow adapter, and there is no or only negligibly small air flow in the collecting region.

Advantageously, it can be provided that a drain channel arrangement fluidly connects the collecting area of the at least one flow adapter and a drip area of the at least one housing. Due to the drainage channel arrangement, the water separated in the filter element can flow from the respective housing into the collecting area of the at least one flow. mungsadapters be guided against the flow direction. The collecting area of the flow adapter lies outside the air flow, so that the flow of water into the collecting area of the flow adapter does not counteract any flow resistance to the water separated in the filter element. For deriving the water separated from the collecting area in the filter element, the at least one flow adapter can have an adapter outlet opening leading outwardly from the collecting area, which is connected in an idential manner to the outlet channel arrangement. Consequently, the water separated in the filter element can be conducted out of the respective housing into the collecting area of the flow adapter against the direction of flow without any or with a small flow resistance under the action of gravity. Within the flow adapter, the water separated in the filter element can then be conducted to the adapter outlet opening and further outward under the influence of gravity, with little or no resistance to flow. In this advantageous manner, removal of the water deposited in the filter element at each operating point of the aeration device can be ensured without an additional application of force. In particular, additional lines and pumps can thereby be omitted for discharging the water separated in the filter element.

In a development of the ventilation device according to the invention, it is advantageously provided that the drain channel arrangement is formed in a coupling frame, which is airtight between the at least one housing and the at least one flow adapter transversely to the flow direction. The coupling frame thus connects the respective housing with the at least one flow adapter in the flow direction air-conducting and transversely to the flow direction by abutment of the coupling frame at the sealing edge of the at least one filter element airtight. In particular, this the pressure chamber of the aeration device be sealed and maintained. The coupling frame may also perform a supporting function and stabilize the ventilation device against deformation. The drainage channel arrangement is formed in the coupling frame, so that the water deposited in the filter element can be conducted from the drip area of the respective housing via the coupling frame into the collecting area of the at least one flow adapter. Subsequently, the water separated in the filter element can be conducted out of the collecting area of the at least one flow adapter to the outside through the adapter outlet opening. The drainage channel arrangement can fluidically connect the drip areas of the plurality of housings to the collection area of the at least one flow adapter or the drip areas of the plurality of housings to the collection areas of the plurality of flow adapters.

Advantageously, the drainage channel arrangement can have at least one horizontal channel channel, which is fluidically connected to a drip area of at least one of the housings. In the operating state, the channel channel is aligned horizontally with a deviation of up to 10 ° to the ground in order to be able to guide the water separated in the filter element horizontally in the ventilation device under the action of gravity. In this case, the individual channel channel fluidly connect the Abtropfbereiche the plurality of juxtaposed housings with the corresponding filter elements. Advantageously, the drainage channel arrangement can have at least two channel channels arranged one above the other, which are fluidically connected to one another by at least one vertical outlet channel. The superimposed channel channels connect the drip areas of the housing in each case a horizontal row and the at least one vertical drain channel connects the channel channels vertically fluidly with each other. The vertical discharge channel is vertical in the operating state with a deviation of up to 10 ° to the ground. tet so that the water separated in the filter element can be conducted, under the action of gravity, from a gutter channel to the bottom into the gutter channel lower to the bottom. Advantageously, in the drain channel arrangement in this way a discharge of the water deposited in the Filterele water can be ensured at any operating point of the ventilation device without an additional force exclusively under the action of gravity. The water separated in the filter elements can then be led out of the drain channel arrangement into the collecting region of the flow adapter and further outwards. For this purpose, the gutter channel at the lowest point at its lowest point can be fluidly connected to the collecting area of the at least one flow adapter at its lowest point, for example via a drain line. In this advantageous manner, the plurality of housings and the plurality of filter elements are fluidically connected to one another via the drain channel arrangement in the coupling frame, and the water deposited in the plurality of filter elements can be derived in a simplified manner from the ventilation device. Preferably, the at least one channel channel of a U-shaped metallic's profile and the at least one drainage channel formed from a U-shaped or I-shaped metallic profile.

Advantageously, in a further development of the ventilation device, it is provided that the filter element, the housing and the fan each form a ventilation module with a flow area. In this case, a plurality of identical ventilation modules are stacked against one another in such a way that a total flow area of the ventilation device corresponds to a multiple of the flow area of the individual ventilation module. Advantageously, as a result, the ventilation device can be modularly constructed and, depending on the requirements, can be expanded with further ventilation modules. Furthermore, the individually identically designed ventilation modules are simplified relative to one another interchangeable, so that the assembly and maintenance of the ventilation device are simplified.

Advantageously, it can be provided that at least two of the ventilation modules adjacent to the ventilation device each have, on their housings, a cable part recess extending in the flow direction. In this case, the respective cable part recesses rest against one another on the housings of the adjacent ventilation modules in the flow direction and form a cable opening. The cable part recesses can be designed identically, so that a cross-sectional area of the cable opening corresponds to a double cross-sectional area of the individual cable part recess. Through the cable opening, the cable ducts can be guided in the flow direction between the respective ventilation modules, so that electrical components of the ventilation device can be connected to one another in the flow direction before and after the respective ventilation module without an additional space requirement.

In order to be able to stack the individual ventilation modules so that they can be detached from one another, one of the ventilation modules adjacent to the ventilation device can have at least one recess extending in the flow direction and another ventilation module adjacent to the ventilation device at least one of its housing - Mung direction extending shape have. The at least one recess and the at least one formation are engaged transversely to the flow direction and form a so-called tongue and groove connection. The at least one recess and the at least one formation fix the adjoining ventilation modules in a detachable manner in this way. In order to design the respective ventilation modules identically, the at least one recess and the at least one embodiment can be formed on the respective housing. These are suitably located on opposite formed housing sides, so that the stacked one above the other or side by side ventilation modules are releasably fixed to each other.

In a preferred embodiment of the ventilation device is provided that the ventilation device has four ventilation modules and a single flow adapters. The ventilation modules are fixed to a 2x2 stack block detachable to each other and air-conducting by means of a coupling frame to the flow adapter. The respective ventilation modules are configured identically and each have a cuboid housing with a cuboid filter element and a fan. The flow adapter is fixed to the respective ventilation module by the coupling frame.

Advantageously, the coupling frame can have a module support frame enclosing the respective ventilation modules transversely to the flow direction and an adapter support frame carrying the at least one flow adapter. The module support frame and the adapter support frame can be hinged together or slidably supported by a hinge device and fixed to one another by a locking unit. In this advantageous embodiment of the ventilation device, the coupling frame can be opened and, for example, the filter element in the respective ventilation module can be exchanged in a simplified manner. The drain channel arrangement can then be formed, for example, in the adapter support frame. Advantageously, a passage arrangement for the inlet opening of the respective housing can be fixed transversely to the flow direction on the coupling frame. The passage arrangement - preferably a venetian blind arrangement - is provided for controlling the air volume flow through the respective ventilation module.

In an advantageous development of the ventilation device according to the invention, it is provided that the respective fan is controlled by a control device. is controlled. The control device has at least one measuring arrangement for detecting the air volume flow through the respective filter element. The at least one measuring arrangement in this case has a pressure measuring unit for detecting a static pressure, which is arranged within the ventilation device. By means of the pressure measuring unit, the static pressure in the respective filter element can be detected and from this the air volume flow through the respective filter element can be determined. In particular, a direct and inaccurate measurement of the air volume flow in the respective filter housing is dispensed with and the ventilation device can be controlled more precisely.

Advantageously, the respective pressure measuring unit may be fluidically connected to a pressure measuring point or have such a pressure measuring point. The pressure measuring point is arranged inside the housing in the region of the inlet opening and has a measuring opening there. The measuring opening can penetrate the respective housing, so that the pressure measuring unit arranged outside the housing can detect the static pressure within the housing and the filter element. The respective pressure measuring point or its measuring opening can advantageously be arranged in a drip area of the housing. The drip area of the housing corresponds to a drainage zone of the filter element, which is provided for discharging the water separated in the filter element. The drainage zone of the filter element is connected to a filtration zone of the filter element and is arranged transversely to the flow direction below the filtration zone of the filter element. In order to protect the pressure measuring unit or its pressure measuring point from water and dirt, the pressure measuring point can be arranged on a clean side of the filter element in the respective housing. Advantageously, the respective pressure measuring point or its measuring opening can be integrated in a flow-calmed zone of the drip area of the housing or fixed therein. In this case, the flow-calmed zone of the drip area of the housing with a flow-calm zone of the drainage zone of the Fil terelements correspond. In this context, "flow-calmed" means that the air flow present at the pressure measuring point or its measuring opening is negligibly small for a measurement of the static pressure or causes a measurement error of less than 5% in the measurement of the static pressure.

Advantageously, the housing may have a housing frame enclosing the inlet opening with a radially inwardly projecting inlet step. In order to increase the measuring accuracy when detecting the static pressure in the respective through-flow housing, the pressure measuring point can be arranged at the inlet stage. In this case, the measuring opening can be open in the direction of flow and essentially parallel to the flow direction, in this connection with a deviation of up to 30 °. Suitably, the measuring opening is arranged in the respective housing such that no or only negligible small air flow is present at the pressure measuring point or at the measuring opening. In particular, the measured static pressure can thereby be detected independently of the ram pressure prevailing in the respective housing.

In summary, in the ventilation device according to the invention, a first or a renewed sealing with a reduced expenditure of time and effort done.

In summary, the ventilation device according to the invention can be built up in a modular manner and the ventilation modules of identical design can be exchanged for one another in a simple manner. Advantageous further embodiments of the ventilation device also make it possible to separate the water separated in the respective filter element in a simplified manner from the ventilation device derive; to facilitate sealing of the ventilation device; to control the ventilation device more accurately and to better distribute the air flow in the respective filter element.

Further important features and advantages of the invention emerge from the subclaims, from the drawings and from the associated description of the figures with reference to the drawings.

It is understood that the features mentioned above and those yet to be explained below can be used not only in the particular combination specified, but also in other combinations or in isolation, without departing from the scope of the present invention.

Preferred embodiments of the invention are illustrated in the drawings and will be explained in more detail in the following description, wherein like reference numerals refer to the same or similar or functionally identical components.

It show, each schematically

Fig. 1 is a view of a ventilation device according to the invention;

FIG. 2 shows a view of the ventilation device shown in FIG. 1 from the front; FIG.

Fig. 3 is a view of the ventilation device shown in Figure 1 from th th;

FIG. 4 is a side elevational view of the ventilation device shown in FIG. 1; FIG. FIG. 5 is a top view of the aeration device shown in FIG. 1; FIG.

Fig. 6 is a sectional view of the ventilation device shown in Fig. 1;

Fig. 7 is a side view of a ventilation mode of the shown in Fig. 1

Aerator;

FIG. 8 shows a view of the ventilation mode of the ventilation device shown in FIG. 1 from above; FIG.

FIG. 9 is a sectional view of the ventilation mode of the embodiment shown in FIG

Aerator;

FIG. 10 shows a view of a flow adapter of the ventilation device shown in FIG. 1; FIG.

Fig. 11 is a partial sectional view of the flow adapter of the aerator shown in Fig. 1;

FIG. 12 is a rear view of the flow adapter of the ventilation device shown in FIG. 1; FIG.

FIG. 13 is a top view of the flow adapter of the venting device shown in FIG. 1; FIG.

Fig. 14 is a sectional view of the ventilation device shown in Fig. 1; FIG. 15 shows a further sectional view of the ventilation device shown in FIG. 1. FIG.

Fig. 1 shows a view of a ventilation device 1 according to the invention for filtering air and for separating water aerosols from air. The ventilation device 1 is in Fig. 2 from the front; in Fig. 3 from behind; in Fig. 4 from the side; in Fig. 5 from above and in Fig. 6 in section. The terms "front" and "rear" refer here and below to the air flowing through the ventilation device 1, which flows through the built-aeration device 1 in the operating state from "front" to "behind" parallel or nearly parallel to the ground. The terms "top" and "bottom" refer to the orientation of the built-in ventilation device 1 to the ground accordingly. The ventilation device 1 has a total of four ventilation modules 2, the respective ventilation module 2 having a filter element 3, a housing 4 and a fan 5. The ventilation modules 2 are identical and are detachably stacked together to form a stacking block 19, so that a total flow area 6 of the ventilation device 1 corresponds to a multiple of the flow area 7 of the individual ventilation module 2. In the respective ventilation module 2, the filter element 3 is arranged in the respective housing 4 and can be flowed through from an inlet opening 8 to an outlet opening 9 of the housing 4 in a flow direction 10. The respective blower 5 is fixed to the outlet opening 9 in the flow direction 10 behind the respective housing 4. The respective blower 5 is controlled by a control device 27, which has a measuring arrangement for detecting the air volume flow through the respective filter element 3. In Fig. 7 to Fig. 9, the structure of the ventilation module 2 is shown in detail.

Furthermore, the ventilation device 1 has a flow adapter 11 which is fixed at the respective inlet opening 8 in the flow direction 10 in front of the respective housing 4. The flow adapter 11 has two air inlets 12 and an air outlet 13, which fluidly corresponds to the respective inlet opening 8 of the respec conditions housing 4. The flow adapter 11 is in one piece - for example, plastic - and robust, so that the sucked by the respec conditions blower 5 from the outside air is already distributed in the flow adapter 11. The air sucked from the outside then flows evenly over the respective filter elements 3 and these are protected. In Fig. 10 to Fig. 13, the structure of the flow adapter 11 is shown in detail.

In the aeration device 1, the flow adapter 11, the respec ge housing 4 with the respective filter element 3 and the respective fan 5 in the flow direction 10 are successively connected, so that the air through the air inlets 12 of the flow adapter 11 via the air outlet 13 to the input Lassöffnung 8 of the respective housing 4 and further through the respective Fil terelement 3 can flow. The respective filter element 3 has - as shown in Fig. 6 - a clean and a raw side and is formed from a filter material. The filter material is hydrophobic and the water in the intake air will precipitate in a filtration zone 3a on the raw side. The separated in the filter element 3 water then settles under the action of gravity in a drainage zone 3b of the filter element 3 from. The drainage zone 3b adjoins the filtration zone 3a of the filter element 3 and is arranged offset transversely to the flow direction 10 below the filtration zone 3a of the filter element 3.

The filtration zone 3a of the filter element 3 corresponds to a filtration region 4a and the drainage zone 3b to a drainage region 4b of the housing 4. The filtration region 4a and the dripping region 4b of the housing 4 are adjacent to one another. Furthermore, the flow adapter 11 has a flow area 11 a and a collecting area 11 b, which adjoin one another. The flow region 11a of the flow adapter 11 corresponds fluidly to the Inlet openings 8 of the respective housing 4 and the collecting area 11 b is arranged transversely to the flow direction 10 offset below the flow area 11 a. Furthermore, the collecting area 11 b lies outside a main air flow of the flow adapter 11.

The ventilation modules 2 are releasably secured to the flow adapter 11 by a coupling frame 14. For this purpose, the coupling frame 14 has a module support frame 14a enclosing the respective ventilation modules 2 transversely to the flow direction 10 and an adapter support frame 14b carrying the flow adapter 11. The module support frame 14a and the adapter support frame 14b are hinged together by a hinge device 15 and can be fixed to one another by a locking unit 16. Thus, the coupling frame 14 can be opened and, for example, the filter element 3 in the respective aeration module 2 can be replaced in a simplified manner. In the coupling frame 14, a drain channel arrangement 17 is further formed for draining the water separated in the respective filter element 3. The drain channel arrangement 17 - as shown in FIG. 6 - has two horizontal channel channels 17a arranged one above the other and a vertical outlet channel 17b. In this case, the respective channel channel 17a in each case connects the drip regions 4b of the housing 4 of the ventilation modules 2, which are adjacent in series, to the outlet channel arrangement 17, and the outlet channel 17b fluidly interconnects the two channel channels 17a. The drainage channel arrangement 17 allows the water deposited in the respective filter element 3 to be directed outward through the drainage channel arrangement 17 under the action of gravity. The structure of the Ablaufkanalan- order 17 is shown in detail in Fig. 14 and Fig. 15. Furthermore, a passage arrangement 18 - here a Venetian blind arrangement 18a - for the inlet opening 8 of the respective housing 4 transversely to the flow direction 10 is fixed to the coupling frame 14. The passage arrangement 18 is provided for controlling the air volume flow through the respective ventilation module 2. FIG. 7 shows a side view of a single ventilation mode 2 in the ventilation device 1. The ventilation module 2 is also shown in FIG. 8 from above and in FIG. 9 in section. In order to detachably stack the individual ventilation modules 2 against each other to the stacking block 19, the respective ventilation module 2 in the ventilation device 1 has on its housing 4 a recess 20a extending in the flow direction 10 and a formation 20b extending in the flow direction 10. The recess 20a and the shape 20b of the adjacent ventilation modules 2 are engaged transversely to the flow direction 10 and form a so-called tongue and groove connection. In this way, the recess 20a and the formation 20b releasably fix the adjacent ventilation modules 2 to the stacking block 19. The recess 20a and the projection 20b are formed on the respective housing 4 on opposite housing sides 21a and 21c, as is also shown in FIGS. 1 to 6 and in FIGS. 14 to 15.

Furthermore, the respective ventilation module 2 has on its housing 4 on the opposite housing sides 21b and 21d two cable part recesses 22a extending in the flow direction 10. In the stacking block 19, the respective cable part recesses 22a adjoin one another on the housings 4 of the adjacent ventilation modules 2 in the flow direction 10 and form a cable opening 22. The cable part recesses 22a are configured identically so that a cross-sectional area of the cable opening 22 has a double cross-sectional area individual cable part recess 22a corresponds. Through the cable opening 22, the cable lines can be guided in the flow direction 10 between the respective ventilation modules 2, so that electrical components of the ventilation device 1 in the flow direction 10 before and after the respective ventilation module 2 can be connected to each other without an additional space requirement. The cable openings 22 from the abutting Cable part recesses 22a are also shown in FIGS. 1 to 6 and 14 to 15.

In order to fix the filter element 3 in the housing 4 in a manner that is airtight transversely to the flow direction 10, the filter element 3 has a circumferential sealing edge 23 in the respective ventilation module 2. The sealing edge 23 rests on one side on a sealing surface 24 of the housing 4 enclosing the inlet opening 8 and on the other side on the coupling frame 14. The sealing edge 23 is formed on the Fil terelement 3, so that when inserting or replacing the respective filter element 3 in the ventilation device 1 and the sealing edge 23 is inserted or replaced. The sealing surface 24 is formed by a housing frame 25 enclosing the inlet opening 8. For sealing, in each case an elastic seal 26a and 26b is fixed to a housing 4 and the coupling frame 14 facing side surfaces 23a and 23b of the sealing edge 23 - for example glued.

Fig. 10 shows a view of the flow adapter 11. Further, the flow adapter 11 in Fig. 11 is partially in section; in Fig. 12 from the rear and in Fig. 13 from above. The flow adapter 11 has the air inlets 12 and the air outlet 13, which fluidly corresponds to the respective inlet opening 8 of the respective housing 4. The flow adapter 11 is in one piece and preferably molded from plastic. As a result, the flow adapter 11 is robust and the air drawn in from the outside by the respective blower 5 is already distributed in the flow adapter 11 and flows uniformly over the respective filter elements 3. The flow adapter 11 has the flow region 11a and the collecting region 11b, connecting to each other. The flow area 11 a of the flow adapter 11 corresponds fluidly to the inlet openings 8 of the respective housings 4, and the collecting area 11 b is offset transversely to the flow direction 10 below the flow area 11 a. assigns. Further, the collecting portion 11 b is located outside a main air flow in the flow adapter 11th

As already explained in FIGS. 1 to 6, the drain channel arrangement 17 is formed in the coupling frame 14. The latter fluidly connects the collecting area 11b of the flow adapter 11 and the drip areas 4b of the respective housings 4 fluidically with one another. Through the drain channel arrangement 17, the water separated in the filter element 3 can be guided out of the respective housing 4 into the collecting area 17 of the flow adapter 11 in the opposite direction of flow 10. For this purpose, the collecting region 11b of the flow adapter 11 is fluidically connected to the drain channel arrangement 17 via a drain opening 28, the drain channel arrangement 17 being connected to the drain opening 28 at its lowest point in the lower gutter channel 17a via a drain line (not shown here) is. The water deposited in the filter elements 3 is led into the flow adapter 11 through the drain opening 28 and guided outward in the collecting area 11 b of the flow adapter 11 counter to the flow direction 10. The construction of the drainage channel arrangement 17 is shown in detail in FIGS. 6, 14 and 15.

FIGS. 14 and 15 show sectional views of the ventilation device 1. In the ventilation device 1, the individual ventilation modules 2 to the stacking block 19 and, on the other side, the flow adapter 11 are fixed on one side to the coupling frame 14. In the coupling frame 14, the drain channel arrangement 17 is formed, which has two horizontal channel channels 17a arranged one above the other and a vertical outlet channel 17b. The respective channel channel 17a is aligned horizontally in the built-in ventilation device with a deviation of up to 10 ° to the ground in order to be able to guide the water separated in the filter element 3 horizontally in the outlet channel arrangement 17 under the action of gravity. The respective channel channel 17a connects each because the drip areas 4b of the adjacent housing 4 of the ventilation modules 2 in the stack block 19 are connected in series. The two channel channels 17a are vertically fluidically connected via the outlet channel 17b. The vertical drainage channel 17b is vertically aligned in the built-in aeration device 1 with a deviation of up to 10 ° to the ground, so that the water deposited in the filter element 3 is directed from the upper channel channel 17a to the lower channel channel 17a under the action of gravity can. The water separated in the filter elements 3 is then conducted out of the drain channel arrangement 17 into the collecting area 11b of the flow adapter 11 and further outwards. For this purpose, the lower channel channel 17a is fluidically connected at its lowest point by the discharge opening 28 with the collecting area 11b of the flow adapter. In this advantageous manner, the plurality of housing 4 and the plurality of filter elements 3 via the drain channel assembly 17 in the coupling frame 14 are fluidly connected to each other and the separated in the plurality of filter elements 3 water can be easily derived from the ventilation device 1.

In summary, the ventilating device 1 according to the invention can be modularly constructed and the identically designed ventilation modules 2 can be easily exchanged for one another; Furthermore, the water separated in the respective filter element 3 can be diverted from the ventilation device 1 in a simplified manner; A sealing of the ventilation device 1 can be simplified and the ventilation device 1 can be controlled more accurately and the air flow in the respective filter element 3 can be better distributed.

_**********

Claims

claims

1. Ventilation device (1) for filtering air and separating water aerosols from air,

- wherein the ventilation device (1) has at least one filter element (3), at least one housing (4), at least one fan (5) and at least one flow adapter (11),

- wherein the at least one filter element (3) in the at least one housing (4) from an inlet opening (8) to an outlet opening (9) of the at least one housing (4) in a flow direction (10) I uftdurch ström bar fixed lays

- Wherein the at least one fan (5) at the outlet opening (9) in the flow direction (10) behind the at least one housing (4) and the at least one flow adapter (11) at the inlet opening (8) in the flow direction (10) are fixed in front of the at least one housing (4), and

- wherein a coupling frame (14) between the at least one housing (4) and the at least one flow adapter (11) transversely to the flow direction (10) is airtight fixed,

characterized,

the at least one filter element (3) has an encircling sealing edge (23), the sealing edge (23) being secured on one side to a sealing surface (24) of the at least one housing (4) engaging the inlet opening (8) and on the other side to the coupling frame ( 14) and the at least one housing (4) around the inlet opening (8) to the coupling frame (14) transversely to the flow direction (10) seals.

2. Ventilation device according to claim 1,

characterized,

in that an elastic seal (26a, 26b) is fixed to a side surface (23a, 23b) of the sealing edge (23) facing the housing (4) and / or the coupling frame (14).

3. Ventilation device according to claim 1 or 2,

characterized,

in that the at least one flow adapter (11) is integral and preferably made of plastic.

4. Ventilation device according to claim 3,

characterized,

the at least one flow adapter (11) has a collecting region (11b) and a flow region (11a), wherein the flow region (11a) of the flow adapter (11) corresponds to the inlet opening (8) of the at least one housing (4) and conducts airflow Collection area (11 b) transversely to the flow direction (10) offset below the flow area (11 a) and outside of a main air flow of the flow adapter (11) is arranged.

5. Ventilation device according to claim 4,

characterized,

in that a drain channel arrangement (17) fluidly interconnects the collecting area (11b) of the at least one flow adapter (11) and a drip area (4b) of the at least one housing (4) which is connected to a drainage zone (3b) of the at least one filter element (3). for discharging the ment in the Filterele (3) separated water corresponds.

6. Ventilation device according to claim 5,

characterized,

in that the at least one flow adapter (11) has an adapter outlet opening which leads outwardly from the collecting area (11b) and is fluid-conductively connected to the outlet channel arrangement (17).

7. Ventilation device according to one of claims 4 to 6,

characterized,

the drain channel arrangement (17) is formed in the coupling frame (14).

8. Ventilation device according to claim 7,

characterized,

the outlet channel arrangement (17) has at least one horizontal channel channel (17a), preferably of a U-shaped metallic profile, which is fluidically connected to a drip area (4b) of the at least one housing (4).

9. A ventilation device according to claim 8,

characterized,

the outlet channel arrangement (17) has at least two channel channels (17a) arranged one above the other, which are fluidly connected to one another by at least one vertical outlet channel (17b), preferably of a U-shaped or I-shaped metallic profile.

10. Ventilation device according to one of the preceding claims, characterized in that

- That the filter element (3), the housing (4) and the fan (5) each form a ventilation module (2) with a flow surface (7), and - That a plurality of identical ventilation modules (2) to the ventilation device (1) to each other are detachably stacked such that a total flow area (6) of the ventilation device (1) corresponds to a multiple of the flow area (7) of the individual ventilation module (2).

11. Ventilation device according to claim 10,

characterized,

that at least two of the aeration modules (2) adjacent to the aeration device (1) each have a cable part recess (22a) extending in the flow direction (10) on their housings (4), the respective cable part recesses (22a) on the housings (4) of the adjacent aeration modules (2) in the flow direction (10) abut each other and form a cable recess (22).

12. Ventilation device according to claim 10 or 11,

characterized,

that one of the aeration modules (2) adjacent to the ventilation device (1) has on its housing (4) a recess (20a) extending in the flow direction (10) and another of the ventilation modules (2) adjacent to the ventilation device (1) its housing (4) in the flow direction (10) extending formation (20b), wherein the respective recess (20a) and the respective formation (20b) transversely to the flow direction (10) are engaged and the adjacent ventilation modules (2) fixable to each other.

13. Ventilation device according to one of claims 10 to 12,

characterized,

the ventilation device (1) has four ventilation modules and a single flow adapter (11), wherein the ventilation modules (2) form a 2x2 Stacking block (19) are fixed to each other releasably and by means of the coupling frame (14) on the flow adapter (11) are defined air-conducting.

14. Ventilation device according to one of claims 10 to 13,

characterized,

in that the coupling frame (14) has a module support frame (14a) enclosing the respective ventilation modules (2) transversely to the flow direction (10) and an adapter support frame (14b) supporting the at least one flow adapter (11) which can be hinged together by a hinge device (15) mounted displaceably and by a closure unit (16) are fixed to each other.

15. Ventilation device according to claim 14,

characterized,

the drain channel arrangement (17) is formed in the adapter support frame (14b).

16. A ventilation device according to any one of claims 10 to 15,

characterized,

in that on the coupling frame (14) for the inlet opening (8) of the respective housing (4) in each case a passage arrangement (18), preferably a blind arrangement (18a), for controlling the air volume flow through the respective ventilation module (2) transversely to Flow direction (10) is fixed.

17. Ventilation device according to one of the preceding claims, characterized in that

- That the at least one fan (5) is controlled by a control device (27) having at least one measuring arrangement for detecting the Luftvo- lumenstroms by the at least one filter element (3), and - That the at least one measuring arrangement comprises a pressure measuring unit for detecting a static pressure, which is arranged within the ventilation device (1).

18. Ventilation device according to claim 17,

characterized,

the respective pressure measuring unit is fluidically connected to a pressure measuring point or has such a pressure measuring point, the pressure measuring point being arranged inside the at least one housing (4) in the region of the inlet opening (8) and having a measuring opening there.

19. A ventilation device according to claim 18,

characterized,

in that the respective pressure measuring point or its measuring opening is arranged in a drip area (4b) of the housing (4).

20. Ventilation device according to claim 18 or 19,

characterized,

- That the housing (4) has a the inlet opening (8) enclosing housing frame (25) which forms a radially inwardly projecting inlet stage, and

- That the pressure measuring point is arranged at the inlet stage, wherein the measuring opening in the flow direction (10) is open and is aligned substantially parallel to the flow direction (10).

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