EP0539817A2 - Volume flow regulator - Google Patents

Abstract

In a volume flow regulator for an adjustment flap (4), which regulates itself according to an air speed in a pipe section of a ventilation or air-conditioning system, the adjusting flap (4) is to have a rotary element (9) placed on it. In this case, there is connected to the rotary element (9) a damper (15) which contains a sliding piston (22) as damping element. <IMAGE>

Description

The invention relates to a volume flow controller for an adjusting flap which regulates itself according to an air speed in a pipe section of a ventilation or air-conditioning system and which has a rotary element attached to it.

Such volume flow controllers are known in a variety of forms and designs and are referred to as "constant volume flow controllers". They work automatically without auxiliary energy, the adjustment flap being moved by the air speed in the pipe section. The flap is usually arranged centrally and with ball bearings. The adjusting flap can be reset to a desired starting position, for example, by a spring or a controller driven, for example, by an electric motor.

Such an arrangement is similarly described in DE-OS 39 17 360. There, a controller is assigned to a separate setting device for the setting flap, which controller can be controlled by a control unit, in particular by a room thermostat. This will find a default Adjustment flap instead, the further regulation then taking place through the air speed.

However, it is now known that the air speed can fluctuate greatly in a ventilation or air conditioning system. This is not only due to the corresponding fans, but also, for example, to the different consumers that are regulated. Depending on that, an air speed can change very quickly, so that an adjustment flap starts to flutter, which is undesirable.

The object of the present invention is to provide a volume flow controller of the above. Type by means of which the movement of the adjusting flap is limited in a simple manner.

To achieve this object, a damper is connected to the rotary element, which includes a sliding piston as the damping element.

Similar to the shock absorbers in a car, this damper is said to have the effect that irregularities in the air speed do not immediately and equally affect the adjustment of the adjusting flaps.

It is essential that the sliding piston is supported against an inner wall of the damper via elastic elements. As a rule, a cylindrical housing is selected for the damper, in which the sliding piston moves. However, other geometric shapes are also conceivable here and are intended to be encompassed by the inventive concept. If a cylindrical damper housing is selected, at least one annular groove in which an O-ring is seated should be formed in the sliding piston. This arrangement has a very significant advantage. Since the expansion of the sliding piston compared to the damper cylinder changes when the temperature changes, this leads to a different sliding process of the sliding piston within the damper cylinder, the volume flow control being influenced. Even with small differences, the sliding piston within the damper cylinder has an easier or heavier gear. However, this means that the volume flow controller starts to vibrate and can no longer be properly regulated.

This disadvantage is eliminated by the O-ring mounted in the annular groove, which usually consists of an elastic material, such as rubber or plastic. A change in the diameter of the piston does not affect the distance of the piston from the inner wall of the cylinder. It is also possible to adjust the depth of the annular groove and the diameter of the O-ring to one another. This allows a smooth or stiff sliding piston to be selected from the outset, depending on how the damper is to be adjusted. A relatively exact calibration to a desired volume flow at different pressures can be set.

The sliding piston is preferably connected to the rotary element by means of a hook which is connected to the sliding piston in a special way. The sliding piston has a piston partition in its interior, which has a central opening. In this central opening a sleeve is inserted, which is fixed on the hook. Far from the actual hook, the sleeve has a stop shoulder with which it strikes the piston septum. From the other side, an expansion disc is placed on the sleeve, which is designed so that its expansion elements dig into the sleeve material when the expansion disk is pulled off the sleeve. This means that the expansion segments delimit an opening that has a smaller diameter than the sleeve. This is a very simple fixation of the sliding piston on the sleeve.

Otherwise, an air gap is formed between the sleeve and the central opening of the sliding piston, which only allows a limited air flow in both directions. This results in damping.

Of course, it is also conceivable that the hook is firmly connected to the piston and, for example, a limited number of small bores are formed in the piston septum, which allow an air passage to a limited extent. Many configurations are conceivable here and are intended to be encompassed by the inventive concept.

So that the rotary element and thus the adjusting flap can be returned to a desired starting position with a corresponding volume flow, it has proven to be advisable to provide appropriate control devices here. Such a control device can be, for example, a return spring or a similar arrangement. Furthermore, a pre-setting device as in DE-OS 39 17 360 is also possible.

Overall, a volume flow controller is created here, which, with relatively cheap means, allows ventilation systems to be controlled with inexpensive volume flow controllers without electronics and servomotors.

• Figur 1 eine Draufsicht auf einen teilweise geöffneten Volumenstromregler in Gebrauchslage auf einem Rohrabschnitt eines nicht näher dargestellten Lüftungs- bzw. Klimasystems;
• Figur 2 eine Ansicht durch den Rohrabschnitt gemäß Figur 1 mit geöffnetem und teilweise gebrochen dargestelltem Volumenstromregler;
• Figur 3 einen Längsschnitt durch einen erfindungsgemäßen Dämpfer zum Einsetzen in den Volumenstromregler gemäß Figur 1 oder 2;
• Figur 4 einen Querschnitt durch einen erfindungsgemäßen Dämpferkolben.

Further advantages, features and details of the invention result from the following description of preferred exemplary embodiments and from the drawing; this shows in

• Figure 1 is a plan view of a partially open volume flow controller in the use position on a pipe section of a ventilation or air conditioning system, not shown;
• FIG. 2 shows a view through the pipe section according to FIG. 1 with the volume flow controller shown open and partly broken;
• 3 shows a longitudinal section through a damper according to the invention for insertion into the volume flow controller according to FIG. 1 or 2;
• Figure 4 shows a cross section through a damper piston according to the invention.

According to FIG. 1, a volume flow controller 2 is seated on a pipe section 1 of a ventilation or air conditioning system (not shown in more detail). This volume flow controller 2 is connected to a shaft 3 which passes through the pipe section 1 and holds an adjusting flap 4. The shaft 3 is held on both sides in the pipe section 2 by corresponding bearings 5 and 6, the shaft 3 rotating in these bearings 5 and 6 and thus being able to open or close the free cross section of the pipe section 1.

Towards the volume flow controller 2, the shaft 3 also passes through a cage 7 on which a housing 8 of the volume flow controller 2 is seated. In the housing 8 there is a rotary element 9, which is connected via corresponding nuts 10 and 11. The rotating element 9 can rotate in the direction of the double arrow Z, the shaft 3 and thus also the adjustment flap 4 is taken. The corresponding axis of rotation is marked with A.

A chain 12 is attached to the rotating element 9, on which a chain 13 can be pulled. The connection between carriage 13 and chain 12 is not of inventive importance at the moment.

Furthermore, the rotating element 9 can also be, for example, a gearwheel, the teeth of which are connected to a rack or another gearwheel of the slide 13. The only essential thing is that the rotary element 9 can be rotated in the direction of the double arrow Z by a controller or the like, as is shown, for example, in DE-OS 39 17 360, and a presetting of the adjusting flap 4 is thereby possible.

The rotary element 9 is connected eccentrically to a damper 15, which dampens the rotary movement of the rotary element 9 and thus also the adjusting flap 4. In the present case it is a so-called constant volume flow controller, which works automatically without auxiliary energy. The preferably ball-bearing adjustment flap 4 is moved by the air speed. However, so that the adjustment flap 4 does not turn in the direction of the double arrow Z with every slight change in the air speed, this damper 15 is provided. A specific flap position is specified in the factory, but this can subsequently be changed using the slide 13 via the chain 12.

The damper 15 has a damper cylinder 17 and is connected eccentrically via a hook 16 to the rotary element 9, so that it dampens every movement of the rotary element 9, in whatever direction. The damper cylinder 17 is seated in a bearing fork 18 which is connected to the housing 8. For the sake of simplicity, that is Damper cylinder 17 made of plastic, with pins 19 (see FIG. 3) molded onto it, which sit in corresponding bores 20 of the bearing fork 18. With these pins 19, the damper cylinder 17 rotates to a limited extent in the bores 20.

The damper cylinder 17 has a cover 21 through which the hook 16 passes. In the interior of the damper cylinder 17, a sliding piston 22 is provided, which is pushed onto the hook 16. The sliding piston 22 is movably supported relative to the hook 16. This is effected by a sleeve 23 which is firmly connected to the hook 16 and passes through a central opening 25 in a radial piston septum 26 with the formation of a stop shoulder 24.

On the other hand, the abutment shoulder 24 is fitted with a spreading disc 27, which consists of individual, cut-in segments which open a through-opening whose diameter is smaller than that of the sleeve 23. For this reason, these segments deform when pushed onto the sleeve 23 , so that they form an abutment for pulling the spreading disc 27.

Between the sleeve 23 and the central opening 25 in the piston septum 26 there is an air gap through which air can escape from a working space 28 when the sliding piston 22 is pushed in or through which air can be sucked into the working space 28 when the volume of this working space 28 is increased. The gap is chosen so that only a small amount of air can be sucked in or expelled, whereby a simple but effective damping takes place.

Furthermore, the sliding piston 22 has an outer annular groove 30, in which an O-ring 31 is inserted. This o-ring can for example made of rubber. Due to the depth of the annular groove 30 and the diameter of the O-ring, a further adjustment of the damper can take place, the sliding piston 22 being made either smooth or stiff. In this way it is possible to produce a damper 15 in a very simple manner, which maintains exactly the desired volume flow, even if the air flow is subject to strong fluctuations.

In addition, a cover 32 can be placed on the housing 8, which can be fixed by screws 33.

Claims (8)

Volume flow controller for an adjusting flap which regulates itself according to an air speed in a pipe section of a ventilation or air-conditioning system and which has a rotary element attached to it
characterized,
that a damper (15) is connected to the rotary element (9), which includes a sliding piston (22) as a damping element. Volume flow controller according to claim 1, characterized in that the sliding piston (22) is supported via elastic elements against an inner wall of the damper (15). Volume flow controller according to claim 2, characterized in that the damper (15) has a damper cylinder (17) in which the sliding piston (22) is seated, at least one annular groove (30) being formed in the sliding piston, in which an O-ring ( 31) sits. Volume flow controller according to claim 3, characterized in that the damper (15) is adjusted via the ratio of the depth of the annular groove (30) and the diameter of the O-ring (31). Volume flow controller according to at least one of Claims 1 to 4, characterized in that a sleeve (23) is seated in a central opening (25) of the sliding piston (22), forming an air gap, which sleeve on the one hand has a stop shoulder (24) of a piston septum (26) is present, while on the other hand a spreading disc (27) is placed as an abutment. Volume flow controller according to at least one of claims 1 to 5, characterized in that the damper (15) for connection to the rotary element (9) has a hook (16) which is connected to the sliding piston (22) or the sleeve (23) . Volume flow controller according to claim 6, characterized in that the rotary element (9) is connected eccentrically to the hook (16). Volume flow controller according to at least one of claims 1 to 7, characterized in that a return spring and / or a presetting device is assigned to the rotary element (9).

Images