DE544428C - Mixture regulator - Google Patents

Description

In the case of control devices for mixture formation, in the individual branches Throttle points are provided, the pressure gradient of which is determined by regulators connected upstream or downstream be kept the same. If the merging point of the flows is close behind the control point, so in many cases it is sufficient to control the regulator in the sense that they keep the pressures upstream of the throttles the same.

ίο Often, however, the ratio of the Quantities only approximately preserved because the zones of pressure recovery on the way from the throttle points to the mixing point takes place and which has only an irregular relationship to the amount of passage, in the total gradient kept the same by the controllers is included.

For higher demands it is therefore more advantageous to keep the pressure

ao only like those up to the narrowest cross-section of the throttling existing to interact with each other, which is the square of the passage quantities remain sufficiently precisely proportionate.

One has to accept the difficulty here in order to control the relevant Regulator not two pressures, but two pressure differences to balance against each other, for which a special control apparatus is required.

A suitable control apparatus must, if two individual streams are to be mixed, thus be equipped with four pressure chambers. Is known z. B. the use of two mechanically interconnected Diving bells, each of which is in a separate chamber. The ones to be compared Pressure gradients are brought into effect on the inside and outside of both bells and the one initiated thereby joint movement of the bells is transmitted to a control valve, which with the help of an inflowing from any source Control current passes on the desired impulse to the control elements in the individual lines. The arrangement is so mechanical interconnected bells is cumbersome and requires a construction of the bell apparatus that is difficult to access. At the same time, such control apparatuses tend to oscillate or to over-regulate.

According to the invention, instead of two mechanically interconnected bells two separate bells are used, which are housed in a common chamber. Each bell covers two pressure chambers arranged concentrically with one another. One fifth pressure chamber is located above the two bells. The one for the flow rates The significant pressure gradient between two individual lines is fed into the pressure chambers covered by the bells. Each of the two bells actuates a control valve for the adjustment of the in the Serving regulators located on individual lines

Control current. This circuit has the advantage of a simple construction and an enlarged one Security against commuting, as will be explained in more detail below. The apparatus is in Fig. Ι and 2 for a mixing device shown for gas and air.

In the gas line 45 there is the nozzle 46, in the air line 47 the nozzle 48, shown in the drawing as Venturi nozzles. The adjustable control valve 92 and the controller 58 are connected upstream of the nozzle on the gas side. The membrane 59 of the same are given the required pressure pulses by means of two lines 37 °) 37 ^{b leading to the control apparatus 25.}

The control apparatus 25 consists of a housing in which two double bells next to each other 26 and 27 are housed. These consist of two concentric cylinders ao walls, the outer area of which encloses twice the area of the inner and only about needs to reach down to half of the inner one. One at the bottom of both bells Load prevents tipping over. A support body does not need to be attached if there is sufficient gas resp. There is excess air pressure under the bells.

Under the bell spaces 28 °, 29 ° ·, 28 *, 29 ″ lead the supply lines 32, 33, 34, 35. These are connected so that, for. B. in pipe 32 the air pressure pL 2 in the narrowest cross section of the air nozzle 48, in pipe 33 the gas pressure pG τ in front of the gas nozzle 46, in pipe 35 the air pressure pL 1 in front of the air nozzle, in pipe 34 the gas pressure pG 2 in the narrowest cross section of the Gas nozzle works. Air (or gas) is introduced into the upper space 24 of the housing, for example through a line 54, through a throttle 38, so the constant pressure of the air line 47, which also acts in the supply line 35, prevails in front of the throttling.

The bells 2.6 and 27 each serve the plate (cone or ball) 30 ", 30 * of an overflow valve to the base. The seats of the same are attached in the housing cover and consist of tubes 39", 39 *, which through the valve plate 30 °, 30 * are closed when the bells are raised. The tubes 39 ^s and 39 ⁶ have throttle openings 36 ° and 36 * and are connected to the two membrane sides of the regulator located in the gas line by lines 37 ^a and 37 *.

There is now a constant outflow of the air entering through the throttle 38 from the throttle openings 36 ^s , 36 '' with the result that a lower pressure is established above the water level in the housing 25 than in the air supply line 47 or gas supply line 45 and the Bells are raised. Since both bells are of the same size and weight, they control the sum of the pressures below them. Because if z. B. pL ι + pG 2 <pL 2 + pG ι (or what is the same, pL τ - pL 2 <pG τ - pG 2), bell 26 goes up, valve 30 "closes, the pressure in the pipe 39 ° drops , on the other hand, the outflow through chamber 39 * and the pressure therein initially remain, ie the regulator diaphragm is influenced in the sense of restoring equilibrium.

As mentioned above, the described arrangement works particularly favorably in terms of avoiding pendulum motion. Periodic vibrations, which otherwise often interfere with control circuits, occur, if at all, at most as a common up and down movement of both bells at the same rate. As a result, the ^{periodic pressure fluctuations generated in the valve chambers 39 a} and 39 ⁶ and thus on both sides of the regulating diaphragm are not avoided, but they run parallel and cannot influence the diaphragm itself. As a result, the periodic fluctuation is not carried over to the quantity control. The favorable circumstance that a periodic alternating movement of the bells does not occur, but at most a movement in the same direction, is to be ascribed to the influence of the pressure space 24 common to the bells above the water level which is also common to the bells, whose level changes always act on both bells simultaneously, even if the water level movement is through unilateral pressure rise under one of the bells arose.

A certain lag and braking of the controlled regulator diaphragm with respect to the sensitive pressure pulses of the ^{control currents emerging from the chambers 39 ° and 39 δ} can be provided so that there is no over-regulation. For this purpose, throttles 40 "and 4ο ^{6 are} installed in lines 37 ^a and 37 ^&.

In order to achieve in case of sudden changes in the Entnähme despite through the throttling 40 °, 40 * caused retardation rapid readjustment to the prescribed mixture formation, in any way, parallel to the control knob, a quick n ₀ control are provided, which only in larger quantity changes in Activity occurs, but otherwise remains closed.

Claims (1)

Claim: Wet control regulator for the purpose of mixture regulation, characterized in that that two double bells (26 and 27) are arranged in a common container (25) which each include two pressure chambers in which the four pressures of the two for the individual quantities are measured. alleged pressure gradient are initiated and above which a fifth pressure chamber is located, in which a control current enters through a throttling, which then through two of the two Bells controlled overflow valves are distributed in two storage chambers, in which to actuate the in the individual lines suitable pressures are generated. For this purpose ι sheet of drawings