DE964917C - Wind pressure control device for organs - Google Patents

Description

Wind pressure control device for organs The invention relates to a wind pressure control device for organs or other devices operated with compressed air which require constant air pressure but a variable consumption. and are fed with fluctuating fan pressure. It is known (DRP 622097) to hook a floating valve in front of the organ pipe, the outwardly opening valve of which is connected to a movable control member. This limits a control wind space and is influenced by its internal pressure in the opening direction of the valve, but by the pressure of the fan wind in the closing direction. The pressure in the control room depends on. the variable ratio of an inlet opening and an outlet opening. In order to achieve that the pressure of the wind flowing towards the points of consumption despite the variable. Consumption and despite the fluctuating. Blower air pressure remains the same is ingenious. dungs. according to the size ratio of the inlet opening and the outlet opening of the control wind chamber of the floating valve by two organs, one of which on the size of the valve lift and, thus, on the size of this consumption and that responds to pressure fluctuations of the Gehläsewindes, adjustable and therefore holds Control wind chamber maintains a pressure because it compensates for the influences of changing consumption and fluctuating fan pressure.

In organ building, the Windd: rucks-dearein: direction according to the invention the usual ones Complete replacement of magazines and reducing bellows. This control device is also characterized by great accuracy of the mode of operation, low space requirements and low manufacturing costs. While: at the well-known Control device that: control member connected to the valve disk - a membrane is, is preferably instead according to an earlier patent (M: 23388 IX / 5 i a) a. Calving uses movable mf travel in its cylinder. The between The remaining gap between the cylinder and piston forms the inlet opening of the control wind space. This embodiment offers the slight advantage that for the wind pressure control device Metal only: can be used as a building material, increasing operational safety and the service life can be increased.

In. the drawing, in, reproduced the two exemplary embodiments Fig. i a: Longitudinal section through the wind pressure control device for an organ, being. the cross section of the inlet opening of the control wind space through the movement of this: valve disk is variable, while the cross-section of the outlet opening of the control wind space depends on pressure fluctuations in the blower wind.

FIG. 2 shows a longitudinal section corresponding to FIG. 1 through a wind pressure control device for an organ in which the outlet opening of the control wind room is from. the size of the valve lift as well as of. Pressure fluctuations of the blower wind depends, and FIG. 3 shows an illustration of a modification corresponding to the lower part of FIG the device shown in Fig. 1, in which a pressure cell is the output port of the control wind chamber controls.

The cylindrical housing 1, which is divided by a transverse wall 2, has an outer flange. 3, with the help of which it is in an opening in the floor 4 of a wind box 5 is screwed. This wind box eats connected to a blower and is thus supplied with compressed air. For his part, he is at the bottom of a wind chest 8 screwed to the space 7 of which the individual organ pipes are attached.

The devices described below, which are arranged in the housing 1 serve the purpose of reducing the prevailing wind pressure in room 7 as much as possible Maintain unchanged when the compressed air consumption on the part of the organ pipes. fluctuates and if (the air pressure prevailing in room 6 changes.

The bottom of the wind chest 8 has a round opening through which the Housing i protrudes in a sealed manner, so that the upper edge of the housing i is located in the wind chest space 7. This upper edge forms one. Seat for a valve disk G. This is by means of a rod io with a disk i i serving as a piston adjustable connected. The rod io is slidably guided in a sleeve 12, the attached to the housing 1 coaxially to the latter by means of a perforated transverse wall 13 is. For this purpose, the transverse wall sits on an inner shoulder 14 of the housing i and has a central hole for which the flanged sleeve 12 protrudes. The wall of the housing i has between the floor. the wind chest 8 and the bottom 4 of the Wind box 5 openings 2g, through which the compressed air free. Access to the between the valve disk g and the piston disk i i located: chem space 28 receives. Lifts If the valve disc moves away from the valve seat, the wind gets: into room 7. -The housing i is closed at the bottom by a cover 15 sitting on its edge, which has a central hole. In this bore a sleeve 16 is centered, which is flanged to the cover 15, and one pressed into it and protruding at the top Guide pin 17 carries. The free end 18 of this guide pin goes through a with: through the opening 22 of the intermediate floor z. On the end 18 of the pen 17 is a throttle member, in the shape of a conical piston 2o displaceable, in the longitudinal bore of the pin 18 protrudes with a certain margin. This downward tapering calves has at its lower end a flange with which it is flanged to a piston disk i9. A centering shoulder of the piston 2o (is pressed into a central hole in piston disk i9. The piston disk ig with the piston 2o is pulled downwards by tension springs: 2i: that around the sleeve 16 distributed around between the disk 1g and the cover 15 stretched out. Under the influence of these springs see the conical piston 2o on the sleeve 16 to lie against. When it assumes this position, it protrudes a little through the hole 2o of the floor 2 through into the space 2g, the one between the floor. 2 and the piston disk i i is located and connected to the space 28 by a gap is that between the piston disc i i and 'the inner wall of the housing: i remains.

From the windbox space 6 a pipe leads 24 through the side wall of the housing i and into the space 25 of the piston disc 1g and serving lid 15 is located between (the interval, the piston disk 1 9 and the intermediate floor. 2 situated space 26 communicates through: holes 27 with the open air.

The section located above the lowest: position of the piston disk i i the inner wall 3o of the housing (i widens conically in the direction of the Valve disc g.

The mode of operation of the wind pressure control device described is as follows: As long as the pressure p2 to be controlled in the room 7 is just as great as the blower air pressure p in the rooms. 6 and 28, the valve remains closed. Because, on the one hand, the downward pressure acting in the direction of the arrow II on the piston disk 1 i, reinforced by the weight of the valve, which acts in the direction of the arrow I on the! Valve disk g acting, pressure directed upwards the balance, and. on the other hand, the pressures that act from below, on the piston disk ii and from above on the valve disk 9, are approximately equal, because the pressure p2 is approximately equal to the pressure p1 prevailing in the chamber 23. If, however, wind is now removed from the wind chest 8 by operating the organ pipes, so that the pressure p2 in space 7 falls. seeks, then the pressure p1 acting from below on the piston disk ii predominates and lifts the valve 19, io, ii. This valve thus represents a floating valve connected upstream of the organ pipes, the outwardly opening valve element 9 of which is connected to the movable control element ii, which delimits the control wind chamber 23 and is influenced by its internal jerk p1 in the opening direction, but also below the pressure p2 acting in the closing direction. The floating valve is thus a valve that rises "with the wind" and floats when the wind is withdrawn, with essentially the same pressure p2 being established in space 7 as pressure p1 in control wind space 23. The state p2 = p1 is maintained. However, this relationship only applies to small valve strokes. For larger strokes, in the absence of special precautions. p2 become smaller than p1, because with a strong flow the pressure acting on the underside of the valve disk 9 becomes smaller than p and then the valve does not open far enough. To avoid this shortcoming and! p. The wall section 30 is designed to be conical in shape, even when the wind is strong. In this way it is achieved that the inlet opening of the control wind chamber 23 indicated by arrow III is steadily enlarged with increasing valve lift and therefore p1 increases with increasing lift. This increase compensates for the drop in the air pressure acting on the underside of the valve disk 9.

The blower air pressure under pressure p enters chamber 25 in the direction of arrows VI and acts from below on piston disk i9. This is therefore raised together with the conical piston 2o, namely up to a position in which the tension of the springs. 21 maintains equilibrium with the air pressure exerted on the piston disk i9. If the blower air pressure increases, the cross-section through the increases as a result. The outlet opening of the control wind space 23, indicated by arrow IV. Now, however, the air pressure p prevailing in the control wind space 23 depends on the size ratio of the inlet opening III and. the exit port IV. If one designates the opening cross-sections for the inlet and outlet of the air at III and IV with: A and E, then the pressure p1 in the control wind space 23 is determined by the formula The cross-section A of the outlet opening IV, however, now depends on the pressure p, namely it increases when p increases and becomes smaller when p decreases. The strength of this dependency depends on the cone angle of the piston 2o, the area of the piston disk i9 and the force of the springs 21 and can be selected so that the float valve opens less, if p is larger, and opens wider if p is smaller. Thereby the influence of the fluctuating blower pressure p on the working pressure p2 can be switched off, so that not only influences of changing wind extraction by the organ, but also influences of the fluctuating blower pressure p are compensated and the working pressure p remains constant.

The size ratio of the inlet port III and the outlet port IV of the control wind space 2-3 of the float valve 9, io, ii is thus through two organs i i und` 2o adjustable, of which one organ i i to the size of the valve lift and thus on the size of the consumption and the other organ 2o on pressure fluctuations of the blower wind responds. As a result, a pressure is maintained in the stener wind space 23, which in the manner described compensates for the influences of the changing Wind extraction and in front of fluctuations in the 'blower pressure p originate.

While in the embodiment described, the size ratio A: E is changed in that E is a function of. the wind extraction and A is adjustable as a function of fluctuations in the pressure p, FIG. 2 shows an exemplary embodiment in which the ratio A : E is only influenced by changing A. E however. is invariable, and for this purpose, in the embodiment shown in FIG. 2, different from that in FIG. The gap between the piston disk ii and the housing wall 30 ' therefore has an invariable cross section. In order to now change the cross section A of the outlet opening of the control wind chamber: 23 to, depending on the two factors, namely depending on the valve lift and, depending on; from the blower air pressure, the following arrangement is made: The in Fi.g. The rod io shown is replaced by a rod 3 i which is longer than the housing i and the tapered lower end of which is guided in the bore of the bushing 16. On this pole is now. not only the Kolbep disk ii attached, but also a.- control body 32, the outer wall of which is slightly conical and tapered upwards. The piston 20 of Fig. I is replaced by a hollow piston.2o ', which has an annular projection 33 on the inside and with this the control body 32 at a certain distance! surrounds. The interior of the piston 20 ', located below the annular projection 33, communicates through openings 34 with the space 26 which, in turn, as in the embodiment of FIG. the opening 27 Mt is connected to the open air. Otherwise, the embodiment of FIG. 2 corresponds to that of FIG.

The effect is as follows: During the cross section E of the inlet opening of the control wind space 23 remains the same, the cross section A of the outlet opening depends on various factors, namely on the altitude of the determined by the valve lift Control body 32 and the altitude of the determined by the blower air pressure p Piston 2o '. On the one hand, these two factors determine the width of the gap between the annular projection 33 and the control body 32 and on the other hand the width of the gap which the piston 20 forms in the opening 22.

In this case, too, by appropriate dimensioning of the parts achieve that the ratio A: E with fluctuating wind extraction and with fluctuating fan air pressure in a way that changes the working pressure in the Room 7 gets constant.

In Fig. 3 - an embodiment of the invention is shown which differs somewhat from that of FIG. The space 25 of variable volume is namely replaced by a pressure cell 25 ', the corrugated wall 35 on the cover 15 is attached and the upper end wall carries the conical piston 2o. At this Embodiment, the tube 24 opens in the middle of the cover 15. This embodiment offers the advantage that the adjustment of the piston 2o takes place without friction and that the sound of the wind flowing past the piston disk 19 ceases to exist comes.

The exemplary embodiments described can be varied in many ways Modify respect. So it would be possible to change the size ratio A: E by that one leaves A constant and only the cross-sectional size E as a function from. p and makes it adjustable by the valve lift.

Claims (7)

PATENT CLAIMS: i. Wind pressure control device for organs and other devices operated with compressed air, which require a constant air pressure, but have a variable consumption and are fed with fluctuating fan air pressure, consisting of a float valve connected upstream of the device. outwardly opening valve disk is connected to a movable control member which delimits a control wind chamber and is influenced by its internal pressure in the opening direction, but by the pressure of the blower wind in the closing direction, the pressure in the control wind chamber from the variable ratio of an inlet opening and an outlet opening depends, characterized in that the size ratio of the inlet opening (III) and the outlet opening (IV) of the control wind space (23) of the floating valve (9; io) by two organs (z. B. ii, 2o), one of which (ii ) to the size of the valve lift and thus to the size of the consumption and the other (2o) to pressure fluctuations of the blower, vdndes, is adjustable and therefore maintains a pressure in the control wind chamber (23), which the influences of changing consumption and fluctuating blower. jerk compensates. 2. wind pressure control device, in which the control windspace through an inlet opening with the fan windspace and connected to the outside through an exit port. is characterized by that the cross-section of one opening (z. B. III) due to the movement of the valve (9, io) is variable, while the cross section of the other opening (IV) is through Pressure fluctuation of the fan wind is variable. 3. wind pressure control device, in which the control windspace through an entrance opening with the Ge-b.läsewindraum and is connected to the outside through an exit opening, characterized in that that the cross section of the outlet opening both by the movement of the valve (9, io) as well as by pressure fluctuations of the blower wind is variable (Fig. 2). 4. Wind pressure control device according to claim 1, 2 or 3, characterized in that the pressure of the blower wind acts on a spring-loaded control member (ig or 25) through which a member (2o) throttling the output opening (2.2) of the control wind chamber (23) is adjustable . 5. Wind pressure control device according to claim 4, characterized characterized that this was influenced by the pressure fluctuations of the fan wind throttling member (20) a conical piston d; st, which is in the outlet opening (22) of the control wind chamber (23) is displaceable in the direction of the axis. 6. Wind pressure control device according to claim 5, characterized in that the conical piston (2o) 'by a pressure cell (25 ') is adjustable, which is fed with the by the fan Room (6) is in communication. 7. Wind'drucksteuereinrichtung according to claim 2, characterized marked that the one opening (III) from! there is a gap that a das said in claim i movable control member forming piston (i i) with the conical Wall of its cylinder (i) forms.