DE3441295A1 - DEVICE ON FANS FOR CONTROLLING THE AIR VOLUME FLOW - Google Patents

Abstract

1. Device for ventilators (1) in ventilator systems with suction connection pieces (6) integrated within the ventilator casing (2), especially for radial ventilators, for regulating the air volume flow of the ventilator, whereby the induction, in which the wall which separates the inlet chamber (7) from the pressure chamber (5), has one or several openings (12) aligned in it, the area of cross-section of which can be varied using the flaps (13, 14) fitted to the openings, and whereby the flaps are adjustable via rods, characterized by the fact, that the openings (12) are aligned with the suction connection pieces (6), whereby the suction connection pieces (6) from the sole casing wall between the inlet chamber (7) and the pressure chamber (5), that the flaps (13) and their adjusting rods are aligned in the pressure chamber (5) within the casing (2) and that the front edges of the blades of the flaps (13) insert into the inside of the pressure chamber (5) roughly paralel to the axes of the flaps when the openings (12) are opened, and remain in front of the axes fo the flaps (13), seen from the direction (arrow) of the bucket wheel (3).

Description

Device on fans to regulate the air volume flow.

The invention "relates to a device on fans For ventilation systems, especially on radial fans, to regulate the air volume flow of the fan.

In ventilation systems, the air volume flow is required to adapt a system or a process to the circumstances. When using centrifugal fans In a ventilation system, this can be achieved by regulating the fan speed or by throttling of the conveyed air flow or by giving the air flow a twist before it enters the paddle wheel. The control of the swirl of the sucked in air flow has changed from the listed control options proven to be most economical for their economy at relatively low investment costs.

This regulation of the air volume flow by means of the swirl is carried out in known systems by connecting a so-called Swirl throttle reached in front of the fan housing or the intake manifold. This upstream swirl throttle has Guide vanes on, which are adjustable. Depending on the position

SE - 501

the guide vanes of the swirl throttle, the air flow sucked in via the suction nozzle receives a corresponding one Swirl, which "allows the air flow to run in the circumferential direction or transversely to the axial direction of the fan. As a result the effect is that the characteristic curve of the fan changes as a function of the position of the le.itschaufeln the swirl throttle raises or lowers. The drive speed of the fan remains constant over the entire control range. The power requirement of the fan increases or decreases when the characteristic curve changes, which means that it is in partial load operation considerable energy savings are possible in a system. . ■

However, this upstream swirl throttle has the disadvantage on that it is very expensive to manufacture and, apart from the space required, for the cultivation or the installation in a system incurs additional costs.

In the book "Ventilatoren - Design and Operation of Radial, Axial and Tangential Fans" by B.Eck, published at Springerverlag Berlin - Heidelberg - N.Y. 1972

(5th edition), a hydraulic swirl distribution is shown and briefly described on page 356, Fig. 353. With this hydraulic swirl distribution, the swirl throttle with its guide vanes is replaced by an arrangement which is arranged in front of the fan housing or the suction nozzle, or at the point of the suction nozzle on the there is a pipe that connects to the fan housing connected is. The arrangement consists of a piece of pipe that surrounds the pipeline and into which there are two openings air from the pressure chamber of the fan can penetrate into the side wall of the fan housing. The pipe section has two opposing slots as a connection to the pipeline, which are opened by adjustable flaps

oat!

SE - 501

are covered. Will the flaps covering the slots opened, so can about the in the side wall of the fan housing arranged slots compressed air from the pressure chamber of the Yentilatorgehäuses over the the pipeline surrounding pipe section flow through the opened slots into the pipeline. The generated in the pipeline Inflowing air creates a swirl in the sucked in air flow, which is in the circumferential direction or transversely to the axial direction of the fan.

This execution of the swirl generation in the air flow sucked in by the fan inside the pipeline avoids the upstream connection of a swirl throttle, which is very expensive to manufacture, but uses a pipe section surrounding the pipeline in which flaps are arranged in a very small space that must be adjusted so that the between the Pipe section and the pipeline, arranged slots are covered or opened, which requires precise mechanics. This and the additional space required for the pipe section surrounding the pipeline reveals a very complex design that cannot be used in a very confined space. Complex construction and large space requirements in the axial direction have ultimately led to the fact that this construction proposal could not prevail in the construction of fans.

It is therefore the object of the present invention to provide a technically equivalent device for generating swirl create, which without additional space requirement in the axial direction of a fan easier and much cheaper is to be established.

This object is achieved by the measures specified in the characterizing part of claim 1.

-6-

SE - 501

Further developments of the object according to the invention are contained in the subclaims.

The device according to the invention, which is simpler and more cost-effective to manufacture, learns from the Suction nozzle sucked in air flow a swirl, as with the swirl throttle, without such in front of the fan housing to have to install. A thickening of a possibly upstream pipeline by the surrounding die.se Pipe section and the attachment of the mechanism for adjusting the flaps over the slots between the pipe section and the pipeline in a confined space is also omitted. The design proposal in the book "Ventilatoren" sees a design without an upstream pipeline not before and cannot be found in the short text either. Therefore, the device according to the invention is suitable which manages without an upstream® pipeline, especially in confined spaces which the attachment of known swirl devices would not be possible at all. The device according to the invention comes with fewer and more easily adjustable parts than with a swirl throttle or an arrangement for hydraulic swirl distribution is the case, and can also be added to existing systems without additional Space required. Further advantages of the G-egen stand according to the invention are listed in the following description.

The invention; is described using examples. In the drawings shows:

Pig. 1 a fan with an upstream one in the suction direction Swirl throttle in perspective

View,

—7—

SE- ₅₀₁ ^3U1295

Fig. 2 shows a fan according to Pig. 1 with an upstream swirl throttle, seen from the side and shown schematically in section so that the functional parts are visible,

-5 Fig. 3 shows a fan with a device according to the invention, in a perspective view,

4 shows a fan according to FIG. 3, in the representation according to FIG. 2,

Fig. 5 shows a paddle wheel with a suction nozzle without a housing with a further development of the device according to the He

discovery, in perspective,

6 shows a fan with a paddle wheel and a Suction nozzle according to FIG. 5 and a housing shown in dash-dotted lines, in the representation according to Mg. 2,

7 shows a paddle wheel with a suction nozzle without a housing another development of the device according to the invention, in a perspective view,

Fig. 8 shows a fan with a paddle wheel and a suction nozzle and a dash-dotted line drawing

Neten housing, in the illustration according to FIG. 2.

In Fig. 1, 1 denotes a radial fan, on the suction surface 7 ¹ (Fig. 2) of which a known swirl throttle 8 is arranged in the suction nozzle 6, with adjustable guide vanes 10 which are mounted at the points 9. Subsequent to the swirl throttle 8, depending on the system, a longer or shorter pipe 11 is mounted for sucking in the air stream. Inside the fan housing 2 is

-8th-

SE - 501

the impeller 3 of the fan 1 is fastened on a shaft 4 (FIG. 2). The drive of the fan 1, the takes place via the shaft 4 is not shown. The pressure chamber 5 is located in the housing 2 of the fan 1. The pressure chamber 5 is through a suction nozzle 6, which tapers in the direction of the paddle wheel, opposite the suction surface 7 '(Pig. 2) sealed. The suction nozzle 6 itself is firmly connected to the housing 2.

Pig. 2 shows the Pig arrangement described so far. 1, seen from the side and shown schematically in section, so that the puncture parts are visible. In Pig. the drive of the fan 1 via the shaft 4 is not shown. The guide vanes 10 of the swirl throttle 8 are shown in the open position and are in this position approximately parallel to the direction of flow through the Pipe 11 sucked air flow. If you steer the guide vanes 10 from this position, a swirl arises behind the swirl throttle 8 in the sucked in air flow, i.e. the swirl creates a flow which runs transversely to the axial direction and which causes the characteristic curve of the fan 1 is raised or lowered, the speed of the drive being raised or lowered the characteristic of fan 1 remains constant. The power requirement of fan 1 increases or decreases when it is increased or lowering of the characteristic curve accordingly, which results in considerable energy savings in part-load operation of a system possible are. In an economic calculation it turns out to be particularly disadvantageous for the swirl throttle, that it causes losses even when it is fully open and the drive motor consumes more power, compared with a fan without a swirl throttle. In addition, the majority of the known swirl throttles require noticeable axial installation space. As Fig. For example shows very clearly, this swirl throttle is required a considerable amount of space, so that when tight

SE - 501

: j iieD - ■ * aM «ν ρ * - ■» *

Pls seating conditions when installing in a system a swirl throttle 8 is not possible at all.

Pig. 3 shows a fan 1 with a device according to the invention. In the perspective shown Fan 1 is the housing with 2, the impeller with 3, the shaft with 4, the pressure chamber with 5 and the suction nozzle, which the pressure chamber 5 opposite the suction surface 7 '(Pig * 4) concludes, denoted by 6. In the suction nozzle 6, which is firmly connected to the housing 2, there are one or more openings 12 attached, which provides a connection between the pressure chamber 5 and the suction chamber 7 behind the suction nozzle 6 produce. In the example according to Fig. 3, these openings 12 are provided with flaps 13, which via a hinge 13 ' are attached to the suction nozzle 6 and extend in the direction of the pressure chamber 5 via a linkage (not shown) open and close, i.e. the size of the openings 12 from the "completely covered" position to the position "fully open" vary.

Like from Pig. 4, which shows a side view of the arrangement according to Mg. 3, the flap 13 protrudes (only one is visible) in the open position into the pressure chamber 5. It works in two ways, on the one hand When the fan 1 is started up, a pressure arises in the pressure chamber 5, which pressure increases when the flap 13 is open the openings 12 in the suction nozzle 6 directly between the paddle wheel 3 and the suction surface 7 ', i.e. in the suction chamber 7, acts on the sucked air flow. It is created in the sucked in air flow, immediately before entering the pressure chamber 5 via the paddle wheel, a swirl that controls the flow of the sucked air stream - like a swirl throttle 8 (Mg. 1 and 2) - can run transversely to the axial direction and depending on the position of the flaps 13 over the openings 12 in the suction nozzle 6 influences the characteristic of the fan accordingly. The effect of the swirl distribution

-10-

SE - 501

is on the other hand still supported by the shape of the flap 13. In the pressure chamber 5 there is namely a circular air movement which is in the same direction as the direction of rotation of the paddle wheel. The blade of the flap 13 shown in FIG. 3, directed against the air flow, utilizes the kinetic energy of the rotating air flow to give the sucked air an impulse in the same direction of rotation, namely the swirl necessary for regulation. The front edges of the blades of the flaps 13, which run approximately parallel to the axes of the flaps 13, plunge into the interior of the pressure chamber 5 when the openings 12 are opened and, viewed in the direction of rotation (arrow) of the paddle wheel 3, lie in front of the axes of the flaps 13 In the same way, a positive effect is achieved if, as will be described in relation to FIGS. 5 and 6 , the leaves of the flaps 14 protrude into the suction space 7 when the openings 12 are opened. Sufficient space is available in the pressure chamber 5 or within the suction nozzle 6 to arrange the mechanism for adjusting the flaps 13. The same effect can thus be achieved with simple mechanical means as when operating a fan 1 with a swirl throttle 8, as shown and described in FIGS. 1 and 2. The efficiency of the fan 1 with the device according to the invention, as shown in Fig. 3 and 4, is identical to the efficiency of a fan 1 without swirl throttle 8 when the openings 12 in the suction nozzle 6 are closed and corresponds to the control device, ie flap 13 in different open positions Positions, the efficiency using a swirl throttle 8.

FIGS. 5 to 8 show further developments of the device according to the invention, FIG. 5 shows a paddle wheel with a suction nozzle without housing in perspective view. The reference numerals are the same for the same parts as in FIG 3 and 4. The openings 12 in the suction port 6 are in this embodiment a development according to the invention provided with a flap H on the inside

-11-

SE - 501 '

of the suction nozzle 6, that is to say in the suction chamber 7, ^{arranged movably via a G-joint H 1} ", so that the openings 12 with the flaps H. are fully open. Doing so, how about the Pig. 3 and 4, a positive effect is achieved in the same way if the leaves of the flaps 14 protrude into the suction chamber 7 when the openings 12 are opened. The front edges of the blades of the flaps 14, which run approximately parallel to the axes of the flaps 14, dip into the interior of the suction chamber 7 when the openings 12 are opened and, viewed in the direction of rotation of the paddle wheel 3, lie behind the axes of the flaps 14 There is enough space behind the suction nozzle 6 or in the suction chamber 7 to accommodate the mechanism, not shown, for adjusting the flaps 14 from a completely closed position into various intermediate positions up to a completely open position,

Pig. 6 shows an embodiment of a fan 1 according to Mg.5, seen from the side and drawn schematically in section, so that the puncture parts are clearly visible. The effects when the flaps H over the openings 12 are closed or open are the same as in detail in FIG the pig. 3 and 4.

Pig. 7 shows a paddle wheel with a suction nozzle 6 without a housing in a perspective illustration. Purely the same Parts as described so far have been given the same reference numerals. That in Pig. 7 and 8 further illustrated The exemplary embodiment shows, for opening or closing the openings 12, slides 15, which are arranged in a corresponding manner Pührungsbahnen 16 and 17 can slide, of which in the Representation but only one slide 15 can be seen. These guide tracks 16 and 17, as shown in Figures 7 and 8, can both on the suction nozzle 6 inside the pressure chamber 5 and on the inside of the suction nozzle 6 be arranged in the suction chamber 7. The sliders 15 are

-12-

SE - 501

by a linkage (not shown) from the completely closed position of the openings 1.2 through intermediate positions up to the completely open area of the Openings 12 adjustable. Except for the example shown, in which only one slide 15 can be seen, about the circumference of the suction nozzle 6 also distributed several slides 15 arranged with corresponding guides 16 and 17 be. Sufficient space is available in the pressure chamber 5 or in the suction chamber 7 behind the suction nozzle 6 for the not shown To accommodate mechanics for adjusting the slide 15.

Pig. 8 shows the exemplary embodiment according to the invention Pig. 7 seen from the side and shown schematically in section, so that the puncture parts can be seen clearly are. Except for the one illustrated slide 15 with corresponding Guide tracks 16 and 17 can, as already mentioned, be distributed over the circumference of the suction nozzle 6, both in the pressure chamber 5 as well as in the suction chamber 7 behind the suction nozzle 6 two or more slides 15 with corresponding Pührungsbahnen 16 and 17 or other arrangements can be arranged. It is also conceivable for the slides 15 to be vertical to the surface of the slide 15 to attach approaches, the surfaces of which like the leaves of the flaps 13 and H (Fig. 3 to 6) act as ladles in the air flow.

-13-

Claims (10)

• χ 4 ü ϊ · f- ο * ■ * "■ SIEGLE + EPPLE KG - « _q Ventilation systems ^ ^ I 4 U 7000 Stuttgart 51 SE - 501 Claims 1 J device on fans for ventilation systems, in particular on radial fans, for regulating the air volume flow of the fan, characterized in that between the pressure chamber (5) of the fan (1) and the suction chamber (7) for sucking in the air one or more openings (12) are arranged, the area of which can be varied by means of flaps (13, 14) or slides (15) attached to the openings (12). 2. Device on fans according to claim 1, characterized characterized in that the openings (12) in the suction port (6) of the fan (1) are arranged. 3. Device on fans according to one of claims 1 or 2, characterized in that the flaps (13, 14) are movably attached to the suction nozzle (6) ^{via joints (13 1} , H ^1). 4 «device on fans according to one of claims 1 to 3, characterized in that the axes of the blades of the flaps (13, H) run in the axial direction of the fan (1). 5. Device on fans according to one of the claims 1. to 4, characterized in that the slide (15) -in arrangements slidably over the openings (12) are. 2 * ■ VY * SE - 501 6. Device on fans according to one of claims 1 to 5, characterized in that the slide (15) are slidably displaceable in guide tracks C ¹ 6 »17 which are attached to the suction nozzle (6). 7. Device on fans according to one of claims 1 to 6, characterized in that the flaps (13) or slide (15) and the rod adjusting this arranged in the pressure chamber (5) within the housing (2) are. 8. Device on fans according to one of claims 1 to 7, characterized in that the to the axes of the flaps (13) approximately parallel leading edges of the leaves of the flaps (13) when the openings are opened (12) immerse into the interior of the pressure chamber (5), and, in Direction of rotation (arrow) of the paddle wheel (3) seen, lie in front of the axes of the flaps (13). 9. Device on fans according to one of claims 1 to 8, characterized in that the flaps (14) or slide (15) and the rod adjusting it outside the pressure chamber (5) behind the suction nozzle (6) are arranged in the suction chamber (7). 10. Device on fans according to one of claims 1 to 9, characterized in that the to the axes of the flaps (H) running approximately parallel front edges of the flaps (H) when opening the openings (12) in the Immerse the inside of the suction chamber (7) and, viewed in the direction of rotation of the paddle wheel (3), behind the axes of the flaps (H) lie.