DE19957962B4 - Method and apparatus for confining, capturing and exhausting fluid media - Google Patents

Abstract

method for confining, sucking and capturing fluid media by suction and blowing using a suction and detection system, characterized in that blown air volume flows (8, 9) by a drive unit (10) are generated and that the blown air volume flows (8, 9) be conveyed into at least two separate blow-out spaces (12, 13), which are already formed within the impeller assembly (15).

Description

The The invention relates to a method and a device for narrowing, Capture and suction of fluid media by means of suction and blow-out effects using a hood system.

Around the efficiency of suction, z. B. cooker hoods, to increase, become inflows to the filter or suction openings used for example in the form of frontal currents. These currents can either by separate conveyors or by tapping the suction stream. As a general rule the invention is applicable to Gases and liquids, like that that generally of streams is spoken while corresponding operations in the terminology of ventilation technology be expressed by "bubbles".

The prior art is based on the patent DE 39 18 870 C2 as well as the registrations DE 196 13 513 A1 and DE 199 11 850 A1 referenced extractor hood systems using frontal vortex generators. The frontal vortex volume flow has a certain predetermined order of magnitude.

The frontal vortex volume flow is often tapped after the pressure increase by the exhaust fan. The ratio of pipe resistance to resistance for the frontal flow within the device is determined by the ratio of extraction volume flow to frontal volume flow, so that such a device must be adapted to the pipeline. This problem also occurs in air curtain extractors, jet seals, fume hoods (eg DE 32 08 622 C1 ) and the like. Installations in which supply air is used in addition to the exhaust air.

task The invention is a hood system by independent suction and to improve inflow volume flows.

This is according to the invention with the features of the characterizing part of claim 1 and claim 13 reached. Further embodiments of the invention are the subject the dependent claims.

Basically proposed with the invention, with a single drive unit independent from each other To achieve suction and inflow volume flows and to avoid that the pipe resistance on the inflow, z. B. the Blasluft- or frontal vortex volume flow back. The outflow chambers for the Absaugvolumenströme and the Frontal volume flows run separately, However, supplied with the help of the single drive unit, so that these volume flows independent from each other are.

This is z. B. achieved in that the outflow already in the conveyor or just behind it. According to one embodiment The invention can do this by using a plurality of separate wheels, divided wheels multiple spiral taps or by a subdivision directly outside of the impeller can be achieved.

To an embodiment The invention is a double-flow fan for a suction device with Frontal vortex generator used, with a flow of flow the frontal flow and the other volume flow is a suction volume flow.

at another embodiment of the invention are superimposed two or more wheels coaxially arranged, driven by a common motor become. The sucked air is thereby conveyed into two separate blow-off chambers. The wheels are in this case designed so that they have the same outer and / or inner diameter have the same or different height, the diameter the wheels otherwise formed differently, or the profiling the blades of the two wheels is designed differently. Crucial for these different variants is that the desired flow rates for the Blowing air and for the exhaust air with the desired pressure increases can be adjusted. The sealing of the blow-off rooms expediently takes place from each other already between these wheels or in a double impeller characterized in that between the wheels a Intermediate ring is inserted, or between the wheels one Nut is provided, into which engages the partition between the Ausblasräumen.

The inflow is expediently already in front of the wheels by means of separating elements, preferably downstream in relation on the filter surfaces, divided. Leave it a more appropriate separation the volume flows achieve.

at another embodiment The invention is a fan used with a high impeller, whose blow-out through a Wall is divided, which optionally formed adjustable in height is. By appropriate displacement of the wall in height can The relationship the subsidized flow rates be set.

In a specific embodiment of a typical extractor hood with a boundary wall between the blowing chambers perpendicular to the fan axis, a separate tap is provided, referred to as a "horizontal tap" Room separation then inserts directly behind the impeller next to a joint. In this embodiment of an extractor hood, a high-altitude impeller is used. The blow-out space for the blown air has a central deflection wall which is arranged between the blower and the frontal vortex generator in order to achieve an air guidance of the blown air flows from outside to inside.

at a further embodiment an extractor hood becomes a blowroom separation with walls parallel to the blower axis used. Here is an air guide housing with multiple spiral taps provided to different sizes blow-out to achieve. A spiral tap is provided for the suction volume flow, additional spiral outlets supply the inflows for the frontal vortex generator. The blast air is in two with the help of a diverting and dividing wall streams divided from the outside to flow inward. This has advantages for the structure of the blow-out flow, then from the outside is directed inward. This is particularly useful for frontal vortex generators, which work with continuous slots.

at a special and particularly simple embodiment of the invention proposed an arrangement with a single fan, wherein in the Unlike traditional Front hoods with two blowers Blowing air and exhaust air separated from each other in a blow-out and a blown air space are. The suction air can be used as recirculation air or exhaust air be used. This results in a particularly advantageous embodiment for low-priced large-volume hoods.

below the invention will be described in connection with the drawing with reference to embodiments explained. It shows:

1 a schematic representation of a blower for a deduction home with two coaxial wheels,

2 another embodiment of the invention with suction space separation,

3 a schematic representation of a hood with the fan according to the invention with two Ausblasräumen and an optional recirculation, in the side view,

4 the representation after 3 in the plan view,

5 another embodiment of a hood according to the invention with multiple spiral for frontal extraction along the section line BB 6 .

6 a plan view of the illustration after 5 .

7 a schematic side view of a fume hood according to the invention with extendable and extended screen, and

8th the appearance of the hood after 7 with retracted screen.

In the presentation after 1 is in a blower housing 1 a supply air opening 2 formed, through which the supply air flow 3 via a supply air guide wall 4 an impeller assembly 5 is fed, consisting of two superposed coaxial impellers 6 and 7 exists, with the impeller 6 a frontal vortex blower and the impeller 7 is a suction fan. The impeller 6 provides a frontal vortex flow 8th , the impeller 7 a suction flow 9 , The wheels 6 and 7 be from a drive unit 10 driven together. They have a common impeller axis 11 , The frontal vortex flow 8th gets into a blow-out room 12 for the frontal flow, and the suction flow 9 in the blow-out room 13 discharged for the exhaust air flow. Both blow-out rooms 12 . 13 are through a partition 14 separated from each other. At the separation point between the two wheels 6 and 7 is (right half of the illustration) a groove 15 provided in the the partition wall 14 engages while on the left side the separation point between the wheels through an intermediate ring 16 closed is.

A modified embodiment of the fan after 1 is in 2 shown. Here is the impeller assembly 5 in the form of two coaxial wheels 6 . 7 different height trained; the two wheels 6 . 7 are through an intermediate ring 16 , the blow-out rooms 12 . 13 for the frontal flow and the exhaust air through a partition 14 separated from each other. The cover side of the blower housing 1 is on the filter surface 17 through a separating plate arrangement 20 for the intake flows into a blown air volume flow 18 and an exhaust air volume flow 19 divided, such that the separation of the inflow 3 already in front of the wheels 6 . 7 takes place, and thus the quality of the separation of the volume flows is improved.

In the 3 and 4 is a frontal cooker hood with a blower and two blower compartments 12 . 13 and an optional recirculation from the blow-out for the exhaust air flow 13 and / or from the blow-out space for the frontal flow 12 shown, wherein the 3 a schematic side view and 4 shows a top view. The extractor hood has a housing 21 with front wall 22 and back wall 23 , an exhaust duct 24 , an impeller assembly 25 , a drive unit 10 , a diversion wall 26 , by the Ge blown air into the blow-out room 13 for exhaust air flow and in the blow-out 12 is divided for frontal flow, a partition wall 27 between the blow-out rooms 12 and 13 passing the blower airflow into a recirculation flow 28 from the exhaust air room 13 and a recirculation flow 29 from the frontal flow room 12 shares a frontal vortex generator 30 and an outlet slot 31 on. The partition 27 that the blow-out rooms 12 . 13 is substantially perpendicular to the fan axis, that is arranged horizontally. This tap is called a horizontal tap. The Ausblasraumtrennung sets directly behind the impeller assembly 25 following a gap 32 one. The deflection wall 26 between impeller assembly 25 and frontal vortex generator 31 is z. B. arranged centrally in the blow-out and results in an air guide the Blasluftströme 33a . 33b from the outside to the inside. This will cause a complete or partial recirculation flow 28 . 29 from the outlet rooms 12 . 13 the frontal flow and exhaust air flow and the exhaust duct 24 into the environment space allows.

Another embodiment of an extractor hood according to the invention is in the 5 and 6 shown. Here, the blowing space separation is performed with parallel to the fan axis arranged walls, and it is a Luftleitgehäuse 34 provided, which the deflecting and dividing walls 26 . 27 after the 3 and 4 equivalent. This air duct housing 34 has several spiral taps 35 . 36 . 37 (The reference lines denote the sealing edges for the respective Ausblasräume), wherein the tap 35 the tap for the suction volume flow is, and the taps 36 . 37 with the left and right inflow the taps for the frontal vortex generator 30 are. The blown air from the impeller assembly 25 is using the air guide 34 in two streams 38 . 39 divided after exiting the hood housing from outside to inside (arrows 40 . 41 ) can flow. This is advantageous for the structure of the blow-out flow, which is then also directed from outside to inside, especially in frontal vortex generators with through-slots.

In the embodiments of the 3 and 4 such as 5 and 6 the hood can with a in the direction of arrow 43 retractable and retractable screen, which is in the 7 and 8th With 42 is indicated, be provided so that the frontal vortex generator 30 a directed against the user of the hood wall 44 for guiding the frontal vortex flow 45 is assigned at the lower end of the housing. The pull-out screen 42 is preferably designed so that the entire blower channel with frontal vortex generator 30 is extendable, as in 7 shown. Here is with 25 a single impeller shown, the two separate Ausblasräumen 12 . 13 is assigned while in 8th instead of a single impeller 25 a double impeller 46 shown is that of two wheels 46a and 46b exists, being compared to the impeller 46a the impeller 46b has a smaller height and a smaller outer diameter with the same inner diameter.

1

fan housing

2

air intake opening

3

supply air

4

Zuluftführungswand

5

truck assembly

6

Wheel as a frontal vortex blower

7

Wheel as exhaust fan

8th

Frontal vortex flow

9

aspiration

10

drive unit

11

common wheel axle

12

Blow out for frontal flow

13

Blow out for exhaust air flow

14

Partition, impellers ( 6 . 7 )

15

groove

16

intermediate ring

17

filter area

18

Blowing air volume flow

19

Exhaust air volume flow

20

Baffles

21

Extractor housing

22

front wall

23

rear wall

24

exhaust duct

25

truck assembly

26

baffle

27

partition wall

28

Recirculation flow from the exhaust air space 13

29

Recirculation flow frontal flow space 12

30

Frontal vortex generator

31

exhaust port

32

gap

33a, 33b

Blasluftströme

34

air guide

35, 36, 37

Spiralabgriffe

38 39

Blasluftströme

40 41

outflow

42

extendable umbrella

43

arrow

44

wall

45

Frontal vortex flow

46

Double impeller ( 46a . 46b )

Claims (24)

A method for limiting, suction and detecting liquid media by suction and blowing out using an extraction and detection system, characterized in that blast air flow rates ( 8th . 9 ) by a drive unit ( 10 ) and that the blown air volume flows ( 8th . 9 ) into at least two separate blow-off spaces ( 12 . 13 ), which are already within the impeller arrangement ( 15 ) are formed. A method according to claim 1, characterized in that the confinement and detection by means of a frontal vortex flow ( 8th ) and / or jet sealing. A method according to claim 1 or 2, characterized in that a supply air flow ( 3 ) partially by a multi-flow impeller assembly ( 5 ) in the form of a suction flow ( 9 ) and a frontal vortex flow ( 8th ) in each case an associated blow-out space ( 12 . 13 ). Method according to claim 1, 2 or 3, characterized in that the volume flows ( 8th . 9 ) for the blast air and the exhaust air by changing the parameters of the impeller assembly ( 5 ) of the trigger system are adjustable. Method according to one of claims 3-4, characterized in that the separation of the supply air flow ( 3 ) in front of the impeller assembly ( 5 ) is made. Method according to one of claims 3-5, characterized in that the separation of the supply air flow ( 3 ) between filter surface ( 17 ) and blower housing ( 1 ) he follows. Method according to one of claims 3-6, characterized in that separation and sealing of the supply air flows ( 3 ) in front of and in the area of the impeller arrangement ( 5 ). Method according to one of claims 1-7, characterized that the promoted currents at least partially recirculated. Method according to one of claims 1-8, characterized in that the volume flows of the recirculation flows ( 28 . 29 ) be managed. Method according to one of claims 1-9, characterized in that the outflow separation outside of the impeller assembly ( 25 ) is carried out. Method according to one of claims 1-10, characterized in that blast air streams ( 33a . 33b ) are guided from outside to inside and that an inwardly convergent flow is generated. Method according to one of Claims 1-11, characterized that controls the outflow volume flows become. Method according to one of claims 1-12, characterized in that when it flows into a plurality of blow-out spaces ( 12 . 13 ) different pressures in the blow-off spaces ( 12 . 13 ) be generated. A method according to claim 1, characterized in that with a conventional radial fan, which has a single impeller, in two separate Ausblasräume ( 12 . 13 ) and the impeller with one with the drive unit ( 10 ) directly connected axis ( 11 ) is operated. Device for confining, extracting and collecting fluid media by means of suction and blow-out devices, characterized in that a multi-flow impeller arrangement ( 5 ) with a supply air flow ( 3 ) and a common drive unit ( 10 ) is provided that the multi-flow impeller assembly ( 5 ) has a double impeller for a suction fan and a frontal vortex blower, and that the wheels ( 6 . 7 ) in a blow-out space forming the frontal flow ( 12 ) and a exhaust air flow forming the blow-out space ( 13 ). Device according to claim 15, characterized in that the wheels ( 6 . 7 ) on a common axis ( 11 ) with this axis driving common drive unit ( 10 ) are arranged. Device according to claim 15, characterized in that the wheels ( 6 . 7 ) have the same diameter. Device according to claim 15, characterized in that the wheels ( 6 . 7 ) have the same height. Device according to claim 15, characterized in that the wheels ( 6 . 7 ) have different height. Device according to one of claims 15-19, characterized in that the blow-out spaces ( 12 . 13 ) by an intermediate ring ( 16 ) between the wheels ( 6 . 7 ) are separated from each other. Device according to one of claims 15-20, characterized in that a groove ( 15 ) between the wheels ( 6 . 7 ) is provided, in which a partition ( 14 ) between the blow-out spaces ( 12 . 13 ) is recorded. Device according to one of claims 15-21, characterized in that the division of the inflow ( 3 ) in front of the wheels ( 6 . 7 ) by means of separating elements. Device according to one of the claims 21-22, characterized in that the partition ( 14 ) between the blow-out spaces ( 12 . 13 ) Is adjustable in height ausgebil det, and that thus the funded flow rates are adjustable. Device for confining, sucking off and detecting fluid media by means of suction and blow-out devices, characterized in that a conventional radial blower is assigned a single impeller which is divided into two separate blow-off chambers (US Pat. 12 . 13 ) promotes.