NO164737B - STROEMNINGSREGULATOR. - Google Patents

Description

The present invention relates to a flow regulator of the type that appears in the preamble to the following independent claim. It is especially intended for gaseous substances, especially for air in air conditioning and ventilation installations.

In known low-pressure regulators, in which the setting value of volumetric flow can be regulated within a relatively wide range, the lowest pressure at which the device starts operating will increase with increasing volumetric flow. Even with small volumetric flow rates, the lowest pressure is relatively high. The highest pressure also increases in accordance with the setting value of the volumetric flow.

Due to the fact that the bottom pressure is high, and/or which depends on the setting value for the volumetric flow, regulators according to prior art, in order to operate correctly, need additional fan energy and potentially a larger fan. These have a great tendency to cause noise problems due to the pressure increase, or a need for damping; they make shaping difficult; they cause difficulties in the execution phase of the installation.

As a rule, in flow regulators are accurate and

stepless setting of the volumetric flow rate at the installation site, especially if the regulator is already installed, very difficult, and in practice often impossible,

nor can the setting value of the volumetric flow rate be read directly. In regulators of a previously known kind, the throttle pressure with which the regulator throttles the current cannot be read either. It is the case that in certain

y

regulator designs of a previously known kind stay within the operating range can be observed from the outside, but their volumetric flow rate cannot be regulated.

A prerequisite for series production, storage, distribution and use of the regulator is that the regulators can be easily and accurately regulated at the installation site even after installation. It is important in terms of balancing and inspection of an air conditioning installation that it is possible to observe from the outside of the regulator what is the set value of the volumetric flow rate, whether the regulator is in the operating range,

and how strongly the regulator throttles. In addition, the basic construction and manufacturing technique must be such that the required calibration measurements are as simple and minimal as possible, and independent of the setting of the volumetric flow.

In previously known regulators, the movement of the regulating element cannot be continuously limited. Therefore, previous regulators cannot be used at all

taken for pure voting without exposing themselves to the risk of binding the device. Second, previous regulators cannot be used for limited bg controlled correction. Thirdly, previous regulators cannot be used in the best possible way in air conditioning installations where the air volumes are varied, such as e.g. different air volumes that run during the day and at night.

In earlier regulators, for counterforce to the regulator element, either a mass or a spring, or a spring and bellows in combination, was used. Each of these designs has its advantages and disadvantages. Disadvantages when using springs are, for example, relaxation of the spring, manufacturing inaccuracies, susceptibility to damage, etc. Disadvantages of a mass, which is used for counterforce, have been that the regulator can only be installed in a horizontal channel, so that the axis should always be horizontal in relation to the flow direction, and that the mass must always be on the same side of the channel. The advantage of a mass being used as counterforce is, for example, reliability in use, good manufacturing accuracy and constancy. Disadvantages of springs plus bellows are that the design is more prone to interference and more expensive than a pure spring, and has a shorter lifespan.

In earlier regulators, to dampen the oscillations in the regulating element, or the so-called chasing, a special dampening device is required. In certain prior designs, a shock absorber or "dashpot" type of damping has been used. In another previous regulator, bellows types have been used for damping. Disadvantages of damping arrangements described above include the fact that the damping arrangements can become jammed over time or they can become blocked or damaged, so that the arrangement needs maintenance, and they can degrade accuracy.

The purpose of the present invention is to provide

an improvement in regulator designs known in the art. A more detailed aim of the invention is to provide a flow regulator in which the disadvantages present in regulators from prior art are overcome.

This is achieved, according to the invention, with a flow regulator of the type mentioned at the outset which is characterized by the features that appear from the characteristic in the following independent claim.

In an advantageous embodiment of the invention, the flow regulator is characterized by the limiters being adjustable. In an advantageous embodiment, the flow regulator is provided with a limiter setting scale. In an advantageous embodiment,

the limiting element has been adapted to lock, if necessary, the regulating element in any given position.

Several advantageous embodiments of the invention are known

drawn in that the regulating element is a slightly curved plate. The angle of rotation between the start and end positions of the regulating element is essentially of the same order of magnitude at different volumetric flow rates when the differential pressure is the same. The operative range of the flow regulator is advantageously changeable by changing the effective flow opening between the regulating element and the flow passage. Likewise, the operative range of the flow regulator is advantageously changeable by means of a shiftable mass which produces a counter-torque,

depending on the position of the regulating element.

With the flow regulator according to the invention, many are achieved

special advantages, where in the flow regulator according to the invention, the movement of the regulating element can be limited, or the movement of the regulating element can, if necessary, be completely stopped. Thanks to certain characteristic features, the flow regulator in the invention can also be used in designs such as

mood, based simply on so-called single-run regula-

clay, whereby there is no risk of binding the device. Second, the flow regulator can be used for limited and controlled correction, and third, the flow regulator can be successfully used in air conditioning installations in which it is desired to change the air flow by centralized influence.

Second, the flow regulator operates in a pre-

relatively wide volumetric flow area, i.e. channel

speed 2-8 m/s, without changing the pressure range in which the flow regulator operates. In addition, the flow regulator operates with a lower differential pressure, e.g. about 20 Pa, than any other regulator known from prior art, in which the operative range is 20 - 200 Pa throughout the line. In the regulator according to the invention, it is understood to use the angle of rotation of the regulating element of about 90°C, whereby by also regulating the effective flow opening, a large movement of the regulating element is achieved in relation to the change in the differential pressures,

and a relatively wide operational area.

Thirdly, in the flow regulator according to the invention, the volumetric flow rate can be regulated steplessly and easily at the installation site, even if the regulator has already been installed on site, simply by turning the regulator knob on the flow regulator. The volumetric flow rate can be read directly on the scale, as well as how much the regulator is throttling, and whether the regulator is in the operative range, i.e. whether the correct amount of air is passing through the flow regulator, or too much or too little.

In the flow regulator according to the invention, a mass is advantageously used as counterforce. In the regulator according to the invention, however, the disadvantages of a mass have been eliminated in practice. The flow regulator according to the invention can be installed in a passage that runs in either direction,

and the mass used as counterforce can be mounted on

both sides of the passage. This is because the axis of rotation of the regulating element is installed horizontally using a leveling device provided in the flow regulator, and the mass is further positioned such that the mass is rotated by an equal amount in relation to the regulating element,

but in the opposite direction, which is the deviation at each moment from a base installation.

The flow regulator according to the invention also does not require separate anti-rotation devices, certainly no anti-rotation device that is prone to bind or collect dirt or to be blocked: essentially,

the back pressure in the passage alone will keep the regulating element stable. The major contribution to this advantageous feature comes from the fact that the regulating element is slightly curved, and that the regulating element does not close the passage completely in any position. Therefore, air is allowed to flow past the regulating element on all sides even when the regulating element is in its "closed" position. Other factors that contribute to the advantageous features described in the foregoing are, for example, the size and shape of the regulating element, the position of the axis of rotation of the regulating element relative to the regulating element, the size and location of the counterweight, and the limiters of the regulatory element.

Thanks to the slightly curved regulating element,

the flow regulator can be manufactured accurately, quietly, and a slightly curved regulating element like this moves smoothly from one end position to the other. The invention is described in detail with reference to an advantageous embodiment of the invention presented in the figures in the accompanying drawings, but to which the invention is not intended to be exclusively limited. Figure 1 presents an advantageous embodiment of the invention in a side projection, partially in section.

Figure 2 shows the section along line II-II in Figure 1.

Figure 3A presents an advantageous embodiment of the regulating element used in the flow regulator according to

the invention, in schematic projection.

Figure 3B presents yet another advantageous embodiment of the regulating element used in the flow regulator according to the invention, in schematic projection. Figure 3C presents a third advantageous embodiment of the regulating element used in the flow regulator according to the invention, in schematic projection. Figure 3D presents a fourth advantageous embodiment of the regulating element used in the flow regulator according to the invention, in schematic projection. Figure 3E presents a fifth advantageous embodiment of the regulating element used in the flow regulator according to the invention, in schematic projection. Figure 3F presents a sixth advantageous embodiment of the regulating element used in the flow regulator according to the invention, in schematic projection. Figure 4A presents in projection the start and end positions of the regulating element of the flow regulator, in case of high volumetric flow. Figure 4B presents in projection the start and end positions of the regulating element of the flow regulator, at small volumetric flows. Figure 5A presents the effective flow opening of the flow regulator according to the invention at least when the regulating element is so regulated that the effective flow opening is large, seen from the flow direction. Figure 5B presents the effective flow opening of the flow regulator according to the invention at least when the regulating element is so regulated that the effective flow opening is small, seen from the flow direction. Figure 5C presents in projection the change of the effective flow opening of the flow regulator according to the invention in a flow passage with variable cross sections. Figure 5D presents in section the change of the effective flow opening of the flow regulator according to the invention by means of separate control elements. Figure 6 presents the principle of limiting the differential pressure range of the flow regulator according to the invention, in a schematic projection.

Figure 7 shows a detail of Figure 6 seen in direction 6A.

Figure 8 presents a way of changing the operative area of the flow regulator according to the invention, in schematic projection.

Figure 9 presents the flow regulator according to Figure 1,

seen in the direction from the cover of the protective housing,

where said cover has been removed.

Figure 10 shows the operative area of the flow regulator according to the invention, in a graphical representation. Figure 11 shows applications of the flow regulator according to the invention in graphic representation.

In the embodiment in Figures 1 and 2, the constant flow regulator according to the invention is essentially indicated by reference number 10. The regulator 10 includes a filter 11 and a regulating element 12 placed in the filter. 11. In the present embodiment, the regulating element is a curved flap-like regulating

which is composed of two curved flaps 12A and 12B, positioned to overlap. The regulating element 12 is attached to a pivot shaft 13 with an adjustment and fastening nut 14 and with a combined sleeve, adjustment and fastening nut 16.

The shaft 13 is rotatably supported in the casing 11 by the bearings 15 and 18. The regulating element 12 rotates in a

flow passage defined by the casing 11. by the action of the air flow, and a counter-torque produced by a weight 23 has been placed to place the regulating element 12 in a position which produces the required throttling effect. The weight 23 is integrally connected to the regulating element 12 by mediation through the sleeve, the adjusting and fixing nut 16 and an element 19 rotatably attached to this and a cover 20, and it rotates together with the rotational movement of the regulating element 12. The shaft 13 is installed horizontally by means of a leveling device and a leveling ball 31 provided in the protective housing.

The operative range of the constant flow regulator 10 with respect to volumetric flow can be changed by turning the control knob 24, whereby in this embodiment the size of the flap-like regulating element 12 and at the same time the effective flow opening, change the location of. the weight 23 and start and stop positioners of the regulating element 12 respectively. The halves 12A and 12B of the flap-like regulating element 12 move relative to each other in different directions due to different directions of the threads on the shaft 13 and in the adjusting nuts 14,16. One end of the shaft 13 has been locked laterally in the bearing 15, whereby under

effect of adjustment moves the element 19 which is rotatably fixed by means of the sleeve 16 to the flap-like

closing element 12, to a half 12b thereof, as well as the cover 20 attached to said element 19, axially in relation to the shaft 13. A gear 22 attached to the cover 20 is in contact with the shaft 13, and the gear 22 is set in rotation on due to the rack and pinion drive which is made up of grooves on the shaft 13 and the lateral movement of the rotatably arranged element 19, whereby the gear 22 simultaneously moves the weight 23 via the rack and pinion 34.

In the figures. 3A - 3F some advantageous embodiments of the regulating element used in the regulator according to the invention are presented, 10. In figures 3A - 3D, the halves in relation to the axis of rotation 13 of the regulating element, - 112a, 112b, 112c and 112d are slightly curved , while in Figures 3E and 3F only half of the regulating element 112e and 112f is slightly curved.

In Figures 4A and 4B, it can be observed that at a high volumetric flow rate, at the smallest differential pressure of the operative area, the regulating element 12 is in a more horizontal position than at a small volumetric flow rate at the corresponding differential pressure.

Likewise, it can be observed that at a small volumetric flow rate at the highest differential pressure of the operative area, the regulating element 12

in a more vertical position than with a large volumetric flow at the corresponding differential pressure.

The position of the regulating element 12 at it

highest volumetric flow rate and at the smallest differential pressure of the operative area deviates about 90°C from the position of the regulating element 12 at the smallest volumetric flow rate and the highest

differential pressure of the operative area. In contrast, the angle of rotation <f>2 is essentially of the same order of magnitude as the respective angle of rotation <t>i for high volumetric flow rates when the differential pressure is the same. Thus, in regulator 10 according to the invention, the angle of rotation <jij, <(>2 of the regulating element 12 for the minimum and maximum differential pressure is essentially of the same order of magnitude at different volumetric flow rates. At the same minimum and maximum values of the differential pressure Ap , the turning angle <j>^, ^ is advantageously around 60°C.

In the embodiments shown in Figures 5A and 5B, in the flow regulator 10 according to the invention, the effective flow opening 37 is changed by regulating the size of the valve-like regulating element 12. In this embodiment, the size of the effective flow opening 37 is changed by move the halves 12a and 12b of the flap-like regulating element 12 in a manner indicated by arrow A

in Figure 5A.

In the embodiment of Figure 5C, the effective flow opening 37 is changed by moving the regulating element 12 in the flow passage 11. 11a with variable cross-section as indicated by arrow B, in other words, by shifting the regulating element 12 in the direction of flow.

In the embodiment of Figure 5D, the effective flow opening 37 is changed by regulating the flow opening by means of a separate regulating element 36, consisting of one or more parts, placed in the flow passage. The axis of the regulating elements 36 is indicated by the reference number 35. The regulating element 36 can be rotated around the axes 35 as indicated by arrows C.

In the flow regulator 10 according to the invention, the differential pressure range is limited by limiting elements 25 and 26a, 26b. When the limiters 26 are moved as indicated by the arrows D in Figure 6, the movement of the regulating element 12 is restricted. The restrictors 26 are advantageously self-regulating in accordance with the volumetric flow rate that has been selected, as shown in Figure 7. The restrictors 26a and 26b have inclined surfaces in that case. The restrictors 26a and 26b regulate themselves when a restrictor pin 25 moves as the volumetric flow rate is regulated, as indicated by arrow E in Figure 7. The movement of the flap-like regulating element 12 of the constant flow regulator 7 can also be stopped totally or partially with the help of the adjustable limiters 26a and 26b. The restrictor pin 25 and the adjustment scale 39 on the protective housing 32 indicate the differential pressure p acting across the constant flow regulator 10. When the restrictor pin 25 touches the restrictor 26a, the differential pressure Ap is at its lowest, and at the restrictor 26b it is at its highest (Figure 7). When the limiter pin 25 is intermediate between the limiters 26a and 26b, the device is in the operative area;

if not, too much or too little air is supplied.

As shown in Figure 8, the operative range of the flow regulator 10 can be changed by means of a movable mass or weight 23 by alternating the weight 23 as indicated by arrow F.

The weight 23 and the limiting elements 25 and 26a, 26b automatically determine different start and end positions of the flap-like regulating element 12 at different volumetric flow rates.

In the constant flow regulator 10, according to the invention, the effect of gravity can be made the same regardless of the installation method by means of the attachable cover 20 which is adjustable in relation to the pivot shaft 13 of the regulating element 12, of the ball housing 29 on the protector housing 32 and of the ball 30 which moves in the housing 29. The constant flow regulator 10 is tuned by a tuning weight 38 in connection with production without the counter-twisting torque produced by the weight 23.

The ball 30 and the scale 40 on the housing 29 show in which position the device is. The cover 20 is turned to a position corresponding to the position indicated by the ball 30 by means of a scale 41 on the cover 20 and locked with a set screw 21.

The operative range of flow regulator 10 according to the invention with regard to volumetric flow rate V can be continuously regulated so that the differential pressure range

in which the flow regulator 10 operates will not change, as presented in Figure 10, or it may be built to change in any desired manner. In Figure 10, the shaded area indicates the area in which flow regulator 10 according to the invention operates. In the example in figure 9, the ratio between the upper and lower pressure of the operative area is 1:10, or e.g. 20:200 Pa, and the ratio 1:4

between the lowest and highest volumetric flow rate V is such that it corresponds to the air flow rate

2-r8 m/s. The operative range of the constant flow regulator 10 is regulated, as already described, by turning the regulation knob 24. The limiter pin 25 on the rotatably arranged element 19, the limiters 26a, 26b changeable in the direction of the shaft 13 and the weight 23 which gives the regulating element 12 different start and end positions at different volumetric flow rates. The end 42 of the gear rack 34 and the volumetric flow rate scale 41 on the cover 20 indicate the air flow to which the constant flow regulator 10 has been regulated. Limiter pin 25 and scale 39

until the restrictor pin 25 on the protective housing 32, in other words, the scale for setting the restrictors 26a and 26b, indicates the differential pressure Ap across the regulator 10. If the restrictor pin 25 is against one or the other restrictors 26a and 26b, the flow regulator 10

not in the operative area, and too much or too little air passes through, the flow regulator 10.

The position of the limiter pin 25 in relation to the scale

39 and the limiters 26a and 26b, can determine from the outside of the device.

In the flow regulator 10 according to the invention, the movement of the regulating element 12 can be limited, or the regulating element 12 can be completely held by means of the adjustable limiters 26a and 26b, which have already been presented above. This gives different possibilities shown in Figure 11.

In the case a) shown in Figure 10, which shows the case where the regulator 10 is only used to tune an air-conditioning installation. When an air conditioning installation is balanced, the regulating element 10 automatically assumes the correct position. Then, the regulating element 10 is held firmly by means of the limiter elements 26a and 26b. The air conditioning installation can be balanced in this way with flow regulators, which means that the air quantities are correct at every point in the air conditioning installation, but the regulator 10 installed in the air conditioning installation does not strive to maintain the volumetric flow rate V unchanged if it tends to change due to an external influence. The air flow can then be changed centrally. Since they are held firmly, there is no danger of the regulators 10 being jammed again.

In case b) shown in Figure 11, it shows case i

which the flow regulator 10 is given a small opportunity for correction, e.g. - 20 Pa. The regulating element 10 assumes the correct position during balancing. The regulating element 12 of the flow regulator 10 is not completely held by the restrictors 26a and 26b in this case; where the regulatory element 12

is rather given a small freedom of movement in both directions. The flow regulator 10 will then, in the case of small pressure variations, correct the volumetric flow rate if the size of the volumetric flow tends to change. On the other hand, if for some reason, the flow regulator 10 becomes jammed again, it will not cause any major failure even then.

The case c) shown in figure 11, shows the case in which the air conditioning installation is balanced with the largest air volume. The flow regulator 10 is used in air conditioning installations where air flows of different sizes are used. Usually, a higher volumetric flow rate is used, for example during the day.

When the air conditioning installation is to be balanced,

the movement of the regulating element 12 is limited by the lower pressure limiter 26a. This achieves that the regulating element 12 prevents an increase in the amount of air during the day, but does not cause any problems whatsoever during night operation when the amount of air is reduced by centralized influence. If the regulating element 12 were allowed to rotate to its fully open position, some points in the air conditioning system during nighttime operation could receive almost as much air as during daytime operation, and other points would correspondingly receive very little.

The distance d) shown in Figure 11 illustrates the case in which the flow regulator 10 is used in air conditioning installations where air flows of different sizes are used. The installation is balanced with a smaller amount of air. The movement of the regulating element 12 of the flow regulator 10 is limited by the upper pressure limiting element 26b. The regulating element 12 cannot turn to its closed position, and the regulating element 12 will thus not cause problems when the air flow is increased by centralized influence.

The case e) shown in Figure 11 illustrates that case

in which the flow regulator 10 is allowed to correct the air flow rate through the differential pressure range in which the flow regulator 10 operates satisfactorily. The limiting elements 26a and 26b are in their extreme positions.

In the foregoing, only some of the advantageous embodiments of the invention have been presented, and it is obvious that various modifications can be made in them within the scope of the inventive idea presented in the claims that follow below. For example, it is not intended to limit the invention exclusively to channels or passages with a circular cross-section.

Claims (10)

1. Flow regulator intended for gaseous substances, in particular for air in air conditioning and ventilation installations including a casing (11) and a regulating element (12) arranged in a flow passage delimited by the casing (11), which regulating element (12) moves automatically in response to changes in the gas flow between a normal position with maximum opening, and a normal position with minimal opening, and maintains between these positions the volumetric flow of the gaseous substance at a desired size with sufficient accuracy when the differential pressure (Ap) acting across the flow regulator (10) varies within given limits, as well as a limiting element (26b) which limits the movement of the regulating element (12), characterized in that the flow regulator (10) includes two fixed or positionable limiting elements (26a, 26b) which limiting element prevents the regulating element (12) in reaching its normal position with max imal opening or reach its normal position with minimal opening in relation to the casing (11) respectively, thereby automatically limiting the differential pressure range in which the flow regulator will operate to maintain the volumetric flow at the desired size, and that the maximum and the minimum limitation of the opening for the regulating element (12), as defined by the limiter elements (26a, 26b), is adjustable. 2. Flow regulator according to claim 1, characterized in that both limiter elements (26a, 26b) are adjustable. 3. Flow regulator according to claim 1 or 2, characterized in that the setting of the volume risk flow rate is changeable by activating an adjustable element (24) and that changing the volumetric flow rate automatically changes the maximum and minimum limit for opening the regulating element (12), as determined by the limiter elements (26a, 26b), in accordance with the change in the flow rate setting. 4. Flow regulator according to claim 3, characterized in that a limiting element (25) cooperates with one of the limiting elements (26a, 26b) at the position with maximum opening of the regulating element (12), and the other of the limiting elements (12b) at the position with minimal opening of the regulating element (12), as the interface between the respective limiting elements (25,26a or 25,26b) assumes an oblique angle in relation to the direction of movement of the respective limiting elements as the regulating element moves, and that there is relative movement between the limiting elements (25 and 26a,26b) at essentially right angles when the volumetric flow rate is adjusted. 5 . Flow regulator according to one or more of the preceding claims, characterized in that the regulating element (12) rotates when the differential pressure (Ap) acting on the flow regulator (10) changes, and that there are two limiting elements (26a, 26b) which are fixed or fixable in position, and a limiting element (25) which moves between the first two limiting elements (26a, 26b) synchronously with the regulating element (12);. 6. Flow regulator according to one or more of the preceding claims, characterized in that the operating area for the flow regulator (10) is changeable by changing the effective flow opening (37) between the regulating element (12) and the casing (11). 7. Flow regulator according to one or more of the preceding claims, characterized in that the flow regulator (10) is arranged with a setting scale (39) for the limiter elements (26a, 26b). 8. Flow regulator according to claim 7, characterized in that the movable limiting element (25) and the setting scale (39) are arranged to indicate the differential pressure (Ap) acting on the flow regulator (10). 9. Flow regulator according to one or more of the preceding claims, characterized in that at least the flow surface of the regulating element (12) which faces the flow of the gaseous substance is somewhat curved or includes two surfaces somewhat inclined in relation to each other. 10. Flow regulator according to one or more of the preceding claims, characterized in that the limiting elements (26a, 26b) are capable of completely stopping the movement of the regulating element (12).