DE2617830A1 - CONTROL VALVE, IN PARTICULAR IN AIR-CONDITIONING SYSTEMS - Google Patents

Description

Dr.-Ing. WALTER STARK

D-4150 Krefeld 1 Moerser Straße 140 Telephone (02151) 28222 and 20469

Date April 22, 1976

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Trox brothers, limited liability company, 4133 Neukirchen-Vluyn, Heinrich-Trox-Platz 3

Control valve, especially in air conditioning systems

The invention relates to a control valve for maintenance a constant volume flow, especially in air conditioning systems with a flow channel, against the action of a spring force from an open to a closed position pivotable flap.

Such control valves are known. In a known embodiment the flap is mounted on a pivot shaft arranged essentially in the center of the flow channel, which is supported on a torsion spring arranged on the outside of the flow channel. To determine the volume flow at different To keep pressure constant on the upstream side of the control valve, the spring must have a characteristic curve whose slope increases with increasing spring deflection. This is the case with the

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Deutsche Bank AG Krefeld 103/1525 bank code 32070080 · Stadt-Sparkasse Krefeld 305722 bank code 32050000 · Poetecheck Essen 4055-431 bank code 36010043

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Known control valve approximately achieved in that the torsion spring is a spiral spring, which up to a pivot angle of the flap of about 30 ° only biegefederartlg and above as Coil spring is stressed. This results in a spring characteristic composed of two straight lines, with the regulation the volume flow is too imprecise. In addition, in the known control valve, the fact that damping of the flap movement is a problem absent, so that uncontrollable flap vibrations and corresponding fluctuations in the volume flow occur can.

In another known control valve, although damping of the flap movement is realized in which the pivot shaft of the The flap is connected to the piston rod of a cylinder-piston assembly via a lever, but there is no spring support the flap, which is held in a position only by weight forces, which is for a certain minimum Pressure on the upstream side of the control valve is designed. Therefore, this control valve can only be used in a very specific way Installation position can be used »

All known control valves are for a certain minimum pressure difference designed and allow the volume flow to be kept constant only in a relatively small area. On the other hand, there is an increasing demand for control valves that have a larger control range and that too are still functional with minimal pressure differences.

The object of the invention is to specify a control valve,

with which a volume flow can be regulated in a large area with little pressure loss and without fluctuations.

This object is achieved in that a sealed bellows is connected to the outflow side of the flap, its interior is in communication with the upstream side of the flap via an opening in the flap.

In this arrangement, the pressure is established through the opening in the flap continues into the interior of the bellows and thereby intensifies the closing moment of the flap. That in turn makes it possible the use of stronger springs, against the action of which the flap must be pivoted from the open to the closed position. Through this smaller hystereses and thus greater control accuracy are achieved. In addition, the valve is already contributing low air velocities. In addition, the arrangement also has so good damping properties that even The flap does not swing open in the event of extreme pressure pulses.

The bellows is supported on a surface which is substantially in one of the pivot axis and the longitudinal axis of the channel formed plane is arranged. As a result, it does not disturb the flow in the canal.

The amplification of the closing moment of the flap can thereby can be improved that on the opening on the upstream side of the flap an angle connector is arranged, the open End «is directed against the direction of flow. This will not only increase the static pressure, but also the dynamic one

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The pressure of the flow is detected and transmitted to the interior of the bellows.

In principle, the control valve according to the invention can with the appropriate Counterbalance can be installed on the flap in any position. In addition, the pivot shaft of the flap have a pin extending through the wall of the channel for a counterweight arranged on a lever, so that a subsequent weight compensation is possible,

The lever is expediently a disc that does not require any additional Torques are transmitted to the pivot shaft.

The above-mentioned disc is used as an abutment for a held on the wall of the channel spring against the Effect is to pivot the flap in the closed position.

If a change in the controlled variable, namely the volume flow, is desired, the spring can also be pivotably mounted on a Control lever, which is articulated to a spindle of a servomotor. remote adjustment of the volume flow is possible «

A further adaptation of the characteristic curve of the restoring force generated by the spring to the transfer function of the control valve can be achieved in that the spring is a helical spring and that between two adjacent turns the helical spring engages an abutment which is displaceable up to a stop. The abutment can in particular

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be a core held by turns, the one in the longitudinal direction the spring extending and through an opening in one has further core guided rod, at the end of which a thickening is arranged as a stop, the dimension of which is larger than the cross section of the opening.

In the following the invention is explained with reference to a drawing showing an embodiment; show it:

Fig. 1 is a schematic representation of a longitudinal section through a control valve for air conditioning systems,

FIG. 2 shows a cross section through another embodiment of the object according to FIG. 1,

3 shows a side view of the object according to FIG. 1, FIG. 4 shows a plan view of the object according to FIGS. -3 _f

5 shows, schematically and partially in section, a return spring in the rest position,

6 shows the spring according to FIG. 5 in a deflected state.

The control valve shown in Fig. 1 has a channel 1 which is formed from a pipe section 2 and through which air flows in the direction of arrow 3. The pipe section 2 has circumferential beads 4, 5 'in the region of its ends so that it extends up to

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these beads in further pipes of an air conditioning Plant can be used.

A pivot shaft 6 is arranged approximately in the middle of the channel 1, which carries a flap 7 which partially covers the channel cross-section in the position shown in solid lines releases and closes the channel cross-section when it is in the vertical line drawn with dash-dotted lines Position.

In the channel 1 there is a stationary plane formed by the axis of the pivot shaft 6 and the longitudinal axis 8 of the channel 1 Plate 9 is arranged on the downstream side of the flap 7. A bellows 10 is connected to the plate 9 in a sealed manner, the other bellows End is connected to the suction side of the flap 7. The interior 11 of the bellows 10 stands above an opening 12 in the Flap 7 with the upstream side of the flap 7 in connection. This means that the static pressure is on the pressure side of the flap also effective in the interior 11 and intensifies the closing moment of the flap 7.

In the control valve shown in FIG. 2 , the same reference symbols denote the same parts. The flap 7 is made somewhat larger than in the control valve according to FIG. 1, so that it already closes the cross section of the channel 1 with the inclined position shown in dash-dotted lines. In addition, the flap 7 carries on its inflow side above the opening 12 an angled connector 13, the open end of which against the flow

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direction (arrow 3) is directed, so that in addition to the static and the dynamic pressure of the flow on the pressure side of the Flap 7 is detected.

While in the control valve according to FIG. 1, the flap 7 is formed by a continuously flat plate, it has it in the control valve according to Fig. 2 in the area of the pivot shaft 6 a step 14, which is followed by a section 16 extending parallel to the section 15 supported on the bellows 10.

As can be seen from FIGS. 3 and 4, the pivot shaft 6 a pin 17 which is passed through the wall of the pipe section 2 and carries a disc 18 on which a Balance weight 19 is attached. The balance weight 19 is arranged so that none resulting from weight forces Torques act on the pivot shaft 6 and the flap 7.

The disc 18 also has an opening 20 into which the end of a helical spring 22 is suspended from a hook 21 is, the other end 23 is articulated at 24 to a pivot lever 25 · The pivot lever 25 is in a Pivot bearing 26 mounted on the wall of the pipe section 2 and with its free end 27 via a joint 28 to a Spindle 29 of a servomotor 30 is connected.

As can be seen from the illustration in FIGS. 3 and 4, the helical spring 22 is not tensioned at all or only slightly tensioned as long as the opening 20 is open when the pivot shaft 6 is pivoted

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or the disk 18 is located in the region of the longitudinal axis 8. The helical spring ZZ is deflected to an increasing extent only at larger swivel angles and thereby generates a corresponding restoring torque in the swivel shaft 6 or a restoring force on the flap 7

³ £ < holding volume flow is used by the servomotor ßr, which can be operated by remote control and which pivots the lever 25 when operated, whereby the helical spring 22 is more or less pretensioned at the same time.

In FIGS. 5 and 6, a helical spring is shown which has a characteristic curve corresponding to the transfer function of the control valve, the rise of which increases with increasing spring deflection. A cylindrical core 31 is inserted into the helical spring, which has a transverse bore for a rod 32, the ends d & n of which project beyond the diameter of the helical spring 22 and which is supported on two adjacent winding sections 33, 34 in each case. The core 31 has a rod 35 which extends essentially in the longitudinal direction of the helical spring 22 and which extends through an opening of a further core 37 held in the helical spring 22 and at its end 38 has a thickening 39 which cannot pass through the opening 36. As can be seen from FIGS. 5, 6, the core 37 also has a rod 40 which is supported on adjacent winding sections 41, 42. In addition, the core 5Ί is held in place with a rod 43.

As a comparison of FIGS. 5 and 6 shows, when arriving

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bring a tensile force to the hook 21 first of all all turns of the helical spring 22 are uniformly deflected, the core 31 is carried along by the winding sections 33, 34 until the Thickening 39 of the rod 35 meets the core 37. If the tensile force is increased further, only the between the hook 21 and the core 31 located turns or, turn sections deflected, because of the associated Reducing the number of turns of the helical spring increases the slope of the spring characteristic accordingly. In order to the characteristic curve essentially corresponds to the transfer function of the control valve shown.

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Claims (9)

Α, η proverbs \
Control valve for maintaining a constant volume flow, especially in air-conditioning systems, with a flap which is arranged in a flow channel and can be swiveled from an open to a closed position against the action of a spring force, characterized in that a sealed valve is attached to the downstream side of the flap (7) Bellows (10) is connected, the interior (11) of which via an opening (12) in the flap (7) with the upstream side of the flap (7) in
Connection. 2. Control valve according to claim 1, characterized in that
the bellows (10) is supported on a surface (9) which is essentially arranged in a plane formed by the pivot axis and the longitudinal axis (8) of the channel (1). 3. Control valve according to claim 1, characterized in that
An angled connector (13) is arranged above the opening (12) on the upstream side of the flap (7), the open end of which is directed against the direction of flow (3), 4. Control valve according to one of claims 1-3, characterized in that the pivot shaft (6) of the flap (7) has a
extending through the wall of the channel (1)
Pin (17) for a mounted on a lever (18) Has counterweight (19). 103844/0401 GRSQSMAL INSPECTED X,. 261783Q 5. Control valve according to claim 4, characterized in that the lever is a disc (18). 6. Control valve according to one or more of claims 1-5 » characterized in that the disc (18) has an abutment (20) for one held on the wall of the channel (1) Has spring (22), 7. Control valve according to claim 6, characterized in that the spring (22) is held on a pivotably mounted adjusting lever (25) which is articulated with a spindle (29) of a Servomotor (30) is connected. 8. Control valve according to claim 6 or 7, characterized in that the spring is a helical spring (22) and that between two adjacent turns (33, 34) of the helical spring (22) an up to a stop (39) displaceable abutment (31, 32) intervenes. 9. Control valve according to claim 8, characterized in that the abutment is one of turns (33, 34) held The core (31) is one which extends in the longitudinal direction of the spring (22) and through an opening (36) in another Core (37) has guided rod (35), at the end (38) of which a thickening (39) is arranged as a stop, the Dimension is larger than the cross section of the opening (36). 1098U / 04Q1