DE3305226A1 - Float-controlled regulator for varying the cross-section of a tube - Google Patents

Description

- 5 - Flow regulation

Float-controlled regulating device for changing of the cross section of a pipe

The invention relates to a float-controlled regulating device according to the preamble of claim 1.

Rain and clarification basins are provided with drainage pipes arranged in the floor area, which lead into a sewage treatment plant. During periods without precipitation, the waste water flows from an inlet pipe into the basin and from there directly through the drain pipe into the sewage treatment plant.

The sewage treatment plants are designed in such a way that they can also absorb a portion of the meteor water that is at Rain falls. In the case of floods, however, the capacity of the sewage treatment plant exceeds the amount of meteor water. That The water level in the basin rises to the level of an overflow arranged in the basin and part of the water then flows directly into one by bypassing the sewage treatment plant

Stream or river.

The amount of water flowing from the drain pipe into the sewage treatment plant is given by the pipe cross-section and the respective water level in the pool. The pipe cross-section must be chosen so that at the highest water level (corresponding to the overflow level) just the maximum amount of water escapes for which the sewage treatment plant is designed is. This has various disadvantages. The inflow to the sewage treatment plant is not constant and this is therefore not evenly utilized. The pipe cross-section is - in adaptation to the overflow level - relatively small and can become clogged easily. The small cross-section has a disadvantage, especially when the tank is empty, if only the dirty water flows through.

The invention now has the task of addressing these disadvantages to eliminate. It should be created an adjustable drain from the liquid basin, such that the Cross-section of the pipe can be varied automatically as a function of the water level. In particular, it should go through the invention be possible to keep the flow rate per unit of time constant at different liquid levels to keep.

This object is achieved according to the invention by the features that are defined in the characterization of claim 1.

Exemplary embodiments are described below with reference to the drawings the invention explained in more detail. Show it:

1 schematically shows a view of the device for adjusting the flow cross section of a
Pipe,

Fig. 2 shows a cross section through the on the pool wall
assembled device according to Fig. 1,

5 shows the geometry of the control device with negative eccentricity,

4 shows the geometry of the control device with positive eccentricity,

5 shows a diagram "A" with hydraulic flow curves,

6 shows a diagram "B" with the geometry of the control device resulting Schlicsskurveri,

7 shows the superimposed diagrams "A" and "B" according to FIGS. 5 and 6,

8 shows a further embodiment of the invention, FIG. 9 shows a closure member designed as a segment,

FIG. 10 is a perspective view of a detail of FIG Control device, and

Fig. 11 the frame with the slide in detail.

In the bottom area of the wall 1 of a clarifier there is a throughflow opening 2, the opening cross section of which can be varied by means of a slide 3. The slide 3 is in two vertical lateral. Guided tours 5 a frame 4 between a lower and an upper end position 21, 22 is mounted adjustable in height. In the Fig. 1 shows the slide 3 in the lower position and the upper position is indicated by dashed lines.

A crank mechanism is provided for adjusting the slide 3. This has a telescopically extendable and fixable in length by means of a cuff 6

Crank rod .7, the lower end of which is articulated (joint 8) with a pin 9 arranged on the slide 3.

The upper end of the connecting rod 7 is via a ball joint TO is connected to a crank arm 11 and can be fixed in length with the further sleeve 6. Since the lengths and / or the points of application of the connecting rod 7 or the crank arm 11 are variable, the corresponding lever arms a, b can be adjusted as desired. The training of the cuff 6 allows the center 10 to the axis 12 and beyond to deliver.

The inner end of the connecting rod 11 is attached to a horizontal axis 12 which is housed in a bearing block 13 is. This bearing block 13 is arranged to be transversely displaceable in two horizontal guides 14 of the frame 4, in such a way that that the eccentricity e can be varied.

The eccentricity e is defined as follows: A perpendicular through the slide pin 9 or the point of application 8 of the The connecting rod 7 is denoted by 15. Another vertical which goes through the pivot axis 12, carry the reference number 16. the distance between these two, in the plane

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of the frame 4 lying perpendiculars 15, 16 from one another is then the eccentricity e.

The axis 12 penetrates one above the drainage opening 2 arranged recess 17 in the wall 1 and leads into the inside of the corner. The implementation is not shown in detail Way sealed.

In the interior of the basin, a float 18 is provided, which can be pivoted at the outer end of a float parallel to the basin wall Float rod 19 is arranged displaceably and lockable. The inner end 20 of the float rod 19 is releasably fixed on the axis 12 such that the Winkeloc between the float rod 19 and the crank arm 11 can be set.

As can be seen from FIG. 1, when the water level H changes by means of the float 18 and the crank mechanism of the slide 3 is adjusted in height.

According to FIG. 1, the slide is located at the upper water level H, in a lower, partially closed position and at the lower water level H ₁ in an upper,

open position, being raised by the amount Ah has been.

The kinematics of the control mechanism can be varied as desired, in particular to achieve a desired constant Flow rate within a certain level range Set Δ H as a function of the changing water level H. To do this, the following parameters must be set: The position of the float 18 on the float rod 19, the angle ° c, the length of the crank arm 11 and the Connecting rod 17, the eccentricity e, the distance k.

The kinematics of the control device can be seen in FIGS. 3 and 4, wherein according to FIG. 3 the between the Stops 21, 22 adjustable slide 3 for regulating the flow opening 2 is used. In Fig. 3 is the eccentricity e negative, while it is positive in FIG. 4.

In order to now adjust the control device so that the flow rate is essentially constant, independently from the water level, the procedure is as follows:

First the hydraulic diagrams "A" (Fig. 5) are calculated. The lines indicated with V ₁ , ν ₂ > ν, are curves of constant water flow (amount per unit of time) for a given pipe cross-section, as a function of the water level H in the basin and as a function of the valve height h from the lower edge of the pipe. Appropriately, corresponding diagrams "A" with the associated hydraulic families of curves V ₁ , V ₂ , v are evaluated for different pipes and recorded on transparent paper.

The diagrams "B" are then calculated and recorded. In these diagrams, the ordinate is again the valve height h and the abscissa is the water level H in the basin. Depending on the selected eccentricity e, the lever lengths a, b, 1 and the pivot angle cC, etc., the movements transmitted by the float to the control device have different effects on the slide 3. _{The closing curves S 1} , S ₂ , s, calculated as a function of the kinematics of the control device, are drawn in diagram "B", such families of curves being created for different eccentricities e and for different pipe diameters. In the diagrams "B", the right branch of the curve corresponds to a negative eccentricity e and the left branch of the curve corresponds to a positive eccentricity e.

In general, the closing curve sections consist of a sinusoidal kinematic curve for the articulated lever mechanism (in the general case for a polygonal articulation, in the special case for a slider crank drive). If γ denotes the angle of rotation between the connecting rod 7 and the crank arm 11, the following relationships result (see FIGS. 3 and 4):

h ₀ = a + 1 / b ² - e ²

(f) = h ₀ -

+ Vb (a sin fe)

h = a cos ^ + Vb - (a sin f- e)

In words: The slide height adjustment Ah as a function of any rotation angle ^ f can be expressed as a function of the crank arm length a, the connecting rod length b, the eccentricity e and the rotation angle γ.

So that the two diagrams "A" and "B" can be related to each other, a relationship between the water level difference ΔΗ = H ₂ - H ₁ and the angle of rotation j ° has to be found. The angle of rotation (f « corresponds to the water level H. and the angle of rotation ty _? Corresponds to the water level H _7. Let ^ ⁷ T * be the angle between the vertical 16 and the float arm 19 at the highest water level H ₂

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draws. The distance between the pivot axis 12 and the pin 9 is denoted by k. Then the following applies:

H (f) = 1 * cos (^ ₁ '+ f) + k

The hydraulic diagrams "A" corresponding to a certain pipe cross-section are now added to the closing diagrams "B" placed. Usually different diagrams have to be selected in order to find optimal coverage. The closing curve piece, which within the selected control range on the hydraulic curve piece for the desired Outflow per second fits best is now marked. This closing curve piece corresponds to certain parameters for the lever lengths, lever position and the eccentricity that can now be set on the control device in order to guarantee the constant flow rate with different Water level.

In Fig. 8 an embodiment of the invention is shown, in which the control device is arranged completely inside the basin. It is shown how by varying the length 1 of the float rod 19, the maximum pivoting range / 3 is increased or decreased can be. The adjustable and non-rotatable lockable

The connection between the float rod 19 and the crank arm takes place by means of a perforated disk 23 and pins 24. So that the flow does not break off and creates eddies, a counter-flow can be installed on the lower edge of the slide 3, be arranged flow-guiding nose 26. This also prevents threads, rags, elongated contaminants from getting around the lower edge to be wrapped.

In FIG. 9, instead of the slide 3, a segment lock 25 is provided which can be pivoted at the end of two bearing blocks 30 is stored. The end of the connecting rod 7 engages in the segment lock 25 in order to pivot it. Of the The pivoting range is again limited by two stops 21, 22. The segment is advantageously considered to be closed Body running.

From the perspective detailed views of FIGS. 10 and 11 further details of the control device emerge. It is shown how the two stops 21, 22 are adjustable are attached to the frame 4 and cooperate with a projection 27 which is arranged on the slide 3 (Fig. 11).

According to FIG. 10 it can be seen how the connecting rod 7 connected to the crank arm 11 by means of the ball joint 10

and how the latter and the float rod 19 are attached to the axle 12 by means of cuffs 28 * The float 18 is arranged displaceably on the float rod 19 by means of a holder 29.

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Claims (12)

DlpL-'Phys. Bure (Dipl.-fj '^ · ^.' RS / bl - 22.1.1982 ί * · '· ■ - *' · ■ '' "" '"■ · Flow regulation G'., ... \ üpp. Walter NILL Schlosserei 8404 Winterthur (Switzerland) Pa te η ta η s ρ r ü che 1. ^ Float-controlled regulating device for changing the flow cross-section of a drain pipe of a liquid basin as a function of the liquid level, characterized in that the float (18) sits on a float rod (19), which is part of a multi-adjustable articulated lever device (7, 11, 19), and that this device acts on a throttle member projecting adjustably into the pipe cross-section (3, 25) acts to change its position as a function of the movements of the swimmer (18). 2. Device according to claim 1, characterized in that the float (18) is displaceable and lockable on the float rod (19) is mounted that the latter and a crank arm connected to it (11) around a pivot axis (12) are pivotably arranged, the float rod (19) and the crank arm (11) form an angle (oC) with each other, and that the connection between the connecting rod (11) and the float arm (19) can be detached and fixed in a rotationally fixed manner to change the angle (oC). 3. Apparatus according to claim 2, characterized in that the crank arm (11) is articulated with a connecting rod (7) is connected, the free end (8) of which engages in an articulated manner in a pin (9) arranged on the throttle element (5), and that the lengths (a, b) of the crank arm (11) and the connecting rod (7) can be varied for the purpose of change the corresponding leverage ratio (a: b). 4. The device according to claim 2, characterized in that it has one on the basin wall (1) in the area of Has a pipe opening (2) arranged holder (4) on which the throttle member (3) is movably mounted, and that the pivot axis (12) sits in a bearing block (13) which is displaceable and lockable in the Bracket (4) is arranged. 5. Device according to claims 3 and 4, characterized in that that between a vertical (15) measured by the pin (9) and a vertical line (16) through the pivot axis (12) and measured as eccentricity (e) defined distance is variable. 6. The device according to claim 1, characterized in that the throttle member is a vertically movable, in two lateral Guides (5) of the frame (4) is mounted slide (3). 7. Apparatus according to claim 6, characterized in that on the lower edge of the slide (3) one against the flow directed nose (26) is arranged. S. The device according to claim 1, characterized in that the throttle member is a pivotable, as a closed Body formed segment (25) is. 9. The device according to claim 1, characterized in that the articulated lever device is arranged outside or inside the pool and the axis (12) is watertight by the Pool wall is performed. 10. The device according to claim 1, characterized in that the throttle member (3, 25) between two adjustable stops (21, 22) is movably arranged. 11. The device according to claim 1, characterized in that the float (18) in one with the basin in communicating Connected container is housed. 12. A method for operating the control device according to claim 1, characterized in that for a certain pipe cross-section, diagrams CA) with families of curves (v .., V ₂ , v ~ ...) of constant water flow are created that further diagrams ( B) be created with families of closing curves (s .., s «, s, ...), which are dependent on the kinematics of the control device, so that the diagrams (A, B) are superimposed to form a closing curve piece (s) to find which fits on a flow curve piece (v) for the desired flow rate per second, and that the setting values (1, a, b, <*., e) assigned to this closing curve piece (s) are set on the control device.