DE202021001159U1 - Energy-efficient deflector hood type EED, as rain protection at the end of an emission source - Google Patents

Abstract

Energy-efficient deflector hood according to the description of Fig. 1 is characterized in that energy-efficient free spaces are available to avoid pressure losses due to the inflowing fluid, e.g. the exhaust air from process exhaust air systems. The fluid outflow area is> the inflow area over the exhaust air duct. The deflector hood is. Inside the deflector hood, there are no fastening struts for holding the water box Fig. 2. The deflector hood Fig. 1 is divided into part 1 and part 2 with 3 via a flange connection. The upper hood part 1 can be removed for cleaning purposes. Made of deformable weather-resistant material of your choice of material types 3).

Description

1) The invention relates to an energy-efficient deflector hood, as a termination of an emission source for the continuation of a fluid into the atmosphere.

Deflector hoods are used as rain protection for emission sources. Deflector hoods are usually designed in a conical and also angular design. A connection to the exhaust air pipe via the roof is made directly with a form-fitting connection and fluid-tight connections. So-called rain collecting trays, also known as water tanks, are installed with a lateral water outlet through pipes into the open air. The side water outlets are subject to contamination, which must be checked and cleaned at shorter intervals as a precaution. The rainwater trays are attached to the inside of the deflector hoods by means of struts. Due to the design, rainwater can flow past the rain pan in extreme weather conditions and get directly into the exhaust air system. The retention of the rain tubs leads to a build-up of fluid, which leads to pressure losses. Depending on the volume flow and entry speed of the fluid into the deflector hood, these amount to approx. 100 - 400 Pascal according to the manufacturer's instructions. So-called Eco deflector hoods with more favorable flow resistances, a continuous, angular rain pan with fastening struts and water outlets through openings in the floor to the outside are also common on the market. These are designed in an angular design. Compared to a round design, this angular design also generates higher wind loads due to the larger outer surface, which has a disadvantage for the structural analysis. The roof anchoring must absorb greater bending moments compared to a round version.

Pressure losses in the deflector hoods usually have to be compensated for in process exhaust air systems via the pressure generator, e.g. fans, by increased pressing. This requires a higher fluid mechanical performance. The use of electrical energy increases proportionally to the efficiency of the pressure generator and thus also the CO2 emissions.

The invention of an energy-efficient deflector hood according to 1-5 differs from the designs offered on the market in that the pressure losses within the deflector hood are very low. The design 1 is completely round. As a rule, exhaust air pipes and fittings according to DIN EN 1506 are used. In terms of pipe diameter D1 The outer dimensions of the deflector hoods, taking into account a free throughflow of the exhaust air, form a modular system according to the dimensions described 2 ). In the case of angular exhaust air ducts, an "adapter" must be provided for the round connection shape of the deflector hood. The water tank after 2 is not attached to the deflector hood with struts or other brackets, but outside of the fluid flow with the drainage pipes 2 part 2 at 1 part 3 adjustable in height according to 3 alternatively 3a attached. The height adjustment allows flow resistances through the water tank 2 and optimally adjust the associated flow noises. The adjustment is made from the outside to the outside 3 without the top hood 1 part 1 must be opened, or alternatively from the inside out 3a by opening the upper hood 1 part 1 . The weather water is via the two water outlet pipes 2 part 2 down through the floor pan 4th part 4th discharged. In the floor pan 4th there is a gully 4th part 5 for the drainage of rainwater, which flows past the water tank in extreme weather conditions and also over 4th part 4th can flow downwards. This means that no water can get into the exhaust air system. The water-carrying components can be opened by opening the upper hood 1 part 1 getting cleaned.

The deflector hood has predetermined dimensions to ensure optimal fluid flow 1 to be observed. The free spaces result in only the slightest pressure loss. Only the funnel-shaped water tank 2 part 1 and the two side drainage pipes 2 part 2 with the upper sliding tube bracket 3 part 2 , are flowed around. The assembly of the components 1-4 can be done on site with a connection to the exhaust air system, this facilitates the transport to the point of use

Dimensions:

In relation to the exhaust air pipe diameter D1 the following dimensions result for the deflector hood 1-4 : (for manufacturing reasons, deviations are permitted) <DN 80: Outer diameter: 4 × D1 / total height: 3 × D1 + (height 1 part 3 ) DN 80- 125: outer diameter: 3 × D1 / total height: 3 × D1 + (height 1 part 3 ) From DN 150: outer diameter: 2 × D1 / total height: 2 × D1 + (height 1 part 3 ) Height 1 part 3 : 200 mm - 250 mm - adjustment height of the water tank 2 : 50 mm -100 mm

Usable material types:

all weather-resistant materials such as plastics such as PE etc., deformable types of steel such as galvanized sheet steel, stainless steels, folded spiral-seam profiles, aluminum, if required painted according to RAL. The types of material can also be mixed, provided that none Galvanic reaction is given, for example, deflector hood made of galvanized sheet steel and the water tank made of plastic.

Implementation guidelines for the deflector hood

• A Material strengths and tightness requirements are to be carried out in accordance with DIN EN 12237.
• B Folded connections on the components 1 - 4th must also be sealed against leaks.
• C Welded flange connections are part with a hole pattern according to DIN 24193 2 , or alternatively with duct clips or other quick-release fasteners, fluid-tight according to specification A.
• D All weld seams must be polished internally in the area of the fluid flow. The weld seams must be weatherproof, e.g. when using galvanized sheets, they must be coated with zinc paint.
• E All external screw connections and other detachable parts on the outer skin must be provided with weatherproof cover caps.

1 Deflector hood, consisting of the parts 1-3 . The flow areas of the fluid within the deflector hood are adequately dimensioned in compliance with the specifications for TA-Luft (technical equipment), exit into the atmosphere, v approx. 5-6 m / s.

part 1 , an upper detachable conical hood with attached pipe section, with removable protective grille at the outlet of the fluid into the atmosphere. 3 eyelets are attached to it as an assembly aid and 2 handles are welded. All-round flange according to the implementation guidelines 4th ) A and C to connect with part 2 .

part 2 , a lower conical hood over the flange connection with part 1 tied together. part 2 becomes part with the pipe section 3.1 airtight connected / welded / riveted.

part 3 , consisting of the parts 3.1 and 3.2 .

part 3.1 , a piece of pipe with part 2 Airtight connected / welded / riveted and end flange according to the execution guidelines 4th ) A and C for connection to the floor pan 4th . Long hole suitable for height adjustment of the water tank 2 and upper hole, matching the profile plate part 3.2 .

part 3.2 , arranged on both sides, a profile plate on part 3.1 welded on. This profile plate has a vertical long hole in the lower area for height adjustment and an upper borehole for fixing and fastening the water tank 2 above 3 part 3 and part 4th .

2 consisting of water tank part 1 and bilateral drainpipes part 2 .

part 1 , funnel-shaped water tank with welded water outlet via molded piece for watertight connection to the drainage pipe part 2 . Funnel inlet rounded to optimize fluid outflow.

part 2 , vertical drainage pipes on both sides with pipe bends and horizontal pipe connections laid with a slope on part 1 . Watertight pipe connections. Provide the pipe ends with a chamfer. Nominal drainage pipe widths: for exhaust air pipes up to DN 125 = DN 15 / from DN 150 = DN 20.

3 Facility on both sides for height adjustment and fixing of the water tank 2 , consisting of the parts 1 - 4th adjustable from the outside without removing the upper deflector hood 1 part 1 .

part 1 , Pressure plate with handle, slidable to cover the long hole in the cover plate part 2 with hole for screwing part 4th and all-round seal.

part 2 Cover plate with long hole as a sliding plate to cover the profile plate 1 part 3.2 in the height-adjustable area, with long hole for guiding parts 4th . The cover plate is provided with a circumferential sealing lip and becomes part of the screw connection 4th and the pressure plate part 1 to the profile plate 1 part 3.2 pressed and seals it after positioning the water box.

part 3 , horizontal and vertical positioning of the water tank on both sides 2 via the drainpipes 2 part 2 , in the upper area of the profile plate 1 part 3.2 arranged, consisting of sliding pipe clamps with sound insulation, fastened via the socket M8 / M10 with threaded rod, firmly screwed from the outside with screw nut, sealing ring and spring washer.

part 4th Fastening of the water tank on both sides 2 via the drainpipes 2 part 2 in the lower area of the profile plate 1 part 3.2 arranged adjustable in height. Pipe clamps with sound insulation are provided as a fixed pipe support, fastened via the socket M8 / M10 with threaded rod, from the outside with screw nut, sealing ring and spring washer over the cover plate part 2 and the pressure plate part 1 , after adjusting the height of the water tank 2 , with the deflector hood 1 part 3 pressure-tight connected.

3 a alternatively to height adjustment from the outside to 3 , is a height adjustment of the water tank 2 by removing the upper deflector hood 1 part 1 , possible from the inside. The long hole in the profile plate 1 part 3.2 not applicable. For the screw connection 3 part 4th a hole is provided. The pressure plate and the cover plate 3 part 1 and part 2 omitted. 3 part 3 , the fastening via sliding pipe clamps is retained. 3 part 4th , the fastening via pipe clamps is retained and is fixed to the deflector hood in the middle position from the outside, with sealing ring, spring washer and screw nut 1 part 3.2 screwed. The height is adjusted from the inside by loosening the fixed pipe clamp connection. After the water tank has been positioned, the pipe clamps are firmly attached to the drainage pipes again 2 part 2 tied together. After that the top hood 1 part 1 put back on and fastened.

Disadvantage: repeated positioning based on the exhaust air operating conditions to minimize pressure loss and minimize flow noise.

4th Floor pan consisting of the parts 1 - 5 ,

part 1 , flat floor pan with end flange according to the execution guidelines 4th ) A and C, to connect with 1 part 3.1 with circumferential piece of pipe fitted into the deflector hood 1 part 3.1 .

part 2 , 2 Pipe pieces in part 1 Welded in to accommodate the water pipes 2 part 2.2 , for draining rainwater down into the open air. Respectively 2 Holes for draining water from the gully part 5 .

part 3 , Fluid inlet made as a cone with a jet angle of 7 ° - 8 ° in the floor pan part 1 Welded in with connection flange suitable for connection to the exhaust air duct.

part 4th circumferential water gutter that is made up of part 1 and part 3 forms,

5 Assembling the components 1-4

Claims (4)

Energy efficient deflector hood as described 1 is characterized in that energy-efficient free spaces are available to avoid pressure losses due to the inflowing fluid, e.g. the exhaust air from process exhaust air systems. The fluid outflow area is> the inflow area over the exhaust air duct. The deflector hood is inside the deflector hood there are no fastening struts to hold the water tank 2 available. The deflector hood 1 is divided into part 1 and part 2 with 3 via a flange connection. The upper hood part 1 can be removed for cleaning purposes. Made of deformable weather-resistant material of your choice of material types 3). Energy-efficient deflector hood, is characterized by the water tank 2 for installation in the deflector hood 1 no struts / brackets required in the inflow area. The attachment of the water tank 2 in the deflector hood takes place via the two drainage pipes 2 Part 2 according to description and sketches 3 or alternatively after 3a . The water intake area of the water tank 2 is> the outflow area of the fluid into the atmosphere. Made of deformable material of your choice of material types 3). Energy efficient deflector hood is characterized by the water tank 2 height adjustable in the deflector hood 1 is attached. According to the description 3 , adjustable from the outside, alternatively according to 3a adjustable from the inside. This height adjustment enables an optimized flow of the exhaust air inside the deflector hood. Pressure losses and flow noise can be minimized. Made from weather-resistant material of your choice of material types 3). Energy-efficient deflector hood, is characterized in that the base plate 4th , with the deflector hood 1 is connected via the flange connection part 1. The fluid flows into the deflector hood via the exhaust air duct into the inlet cone of the base plate 4th Part 3. This inlet funnel / cone has an aerodynamically favorable design and is connected via an airtight connection, eg a flange, adapted to the exhaust air duct. The water outflow from the gutter part 4 takes place via the pipe socket part 2 downwards into the open air, so that no weather water gets into the downstream exhaust air system. Made of deformable weather-resistant material of your choice of material types 3).

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