DE648910C - Centrifugal pump system - Google Patents

Description

The invention relates to a centrifugal pump system with a closing element on the print side. It is characterized by a control piston for the closure member, one side of which with the Working chamber of the pump and the other side of which is connected to the pressure line. The arrangement serves in particular the purpose of securely closing the closure member to be guaranteed even if the pressure in the pressure pipe drops rapidly.

In order to increase the safety of the centrifugal pump system, it is advisable to use in the connecting line leading from the pressure line to the control piston has a compressed air accumulator to turn on. It is so that this accumulator becomes independent of the falling pressure in the pressure pipe expediently in the connecting line leading from the pressure line to the Drudduftakkumulator to install a check valve.

A bypass line can be connected in parallel to the check valve the upright from the compressed air accumulator during the closing process of the closure member obtained pressure automatically to a desired one after the closing process is completed Value drops. It can be useful to provide an adjustable throttle device in the bypass line, in order to be able to adjust the speed at which the pressure in the compressed air accumulator drops as required.

The compressed air accumulator can also have a cylinder side to simplify the system of the Steiier's piston. The control piston can also be designed in this way and install in the pressure pipe of the pump so that it forms the closing element at the same time.

Some embodiments of the subject matter of the invention are shown in the drawing shown schematically.

Fig. Ι shows the changes in pressure during a closing process - Hellendes Diagram;

Fig. 2 shows a section through a first embodiment;

Fig. 3, 4 and 5 show sections through further embodiments.

In Fig. 2, a long pressure pipe b is connected to the centrifugal pump α , in which a closing element c is installed, which has the purpose of automatically closing the pressure pipe to "avoid backflow when the operating pressure which is established in it, e.g. as a result of failure of the pump drive current, drops below a certain amount. The closing element c is automatically controlled by a control piston d , whose right cylinder side causing the opening of the closing element through line e constantly to the working space of the pump α and its left closing the closing element Cylinder side through the connecting line / is constantly connected to a point g of the pressure pipe b located some distance from the pump nozzle.

As a result, the pressure on the closing side of the control piston d when it is started and during normal operation is lower than on the opening side. On the whole, the effect will be that when the pump is started up, it automatically opens, during normal operation it automatically keeps it open and, in the event of a power failure, it automatically closes the closing element.

In the direction of the piston rod of the control piston d , an adjustable stop formed by an adjusting screw h is arranged, by means of which the operating position, ie the open position of the closing element c , can be set by hand as desired. In order to ensure that the closing element c closes reliably even when the pressure in the pressure pipe b drops rapidly, i.e. even when the pressure at g has become approximately equal to the pressure in the working chamber of the pump in rapid succession, there is a pressure accumulator in the connecting line f, z. B. in the form of a known compressed air accumulator i, switched on and this is preceded by a check valve k , which is probably an inflow of funds into the accumulator or to the closing side of the control piston, but not a return flow from the cylinder surrounding the control piston or the accumulator into the Pressure pipe b of the pump permitted. In this way it is achieved that the pressure in the compressed air - ".: ■ accumulator and thus also on the closing side of the control piston, even in the event of a rapid pressure drop in the pressure pipe of the pump, is maintained at the desired level as long as this is necessary for reliable closing of the closing element is required.

In the diagram of FIG. 1, the changes in pressure p that occur during such a closing process are plotted as a function of time t. Line 1 represents the pressure curve at point g of the pressure pipe, line 2 the pressure curve in the compressed air accumulator i and on the left or closing side of the control piston and line 3 the pressure curve in the working chamber of the pump and on the right or opening side of the control piston.

From time i ₀ on, at which the power fails, but the closing element c together with the control piston are still in the position shown in Fig. 2, the pressures in the pressure pipe at g, in the working chamber of the pump α and on the right-hand side of the control piston according to lines 1 and 3 of Fig. 1, which are still coinciding, while the pressure in the compressed air accumulator i and on the left side of the control piston remains almost unchanged due to the air in the accumulator and due to the non-return valve k which prevents backflow (line 2). As a result, the control piston d together with the closing element c is caused by the increasing overpressure prevailing on the left control piston side, which is characterized by the increasing distance between lines 1 and 2 in Fig. 1, with a corresponding displacement of liquid from the right control piston side to the right in shifted the final position, which should be reached at about time t _x. From this point on, the pressures in the pressure pipe and finally also in the accumulator increase again, finally after a few fluctuations they pass into a steady state of rest, which lasts until the system is put back into operation. Occurring as a result of during the closing operation, from the course of the lines 1 and 2 of Fig. Himself ι resulting strong overpressure is achieved in that the closure member C is closed so as energetic, the more rapidly the pressure in the pressure pipe b of the pump α decreases.

The check valve k in Fig. 2 is also connected in parallel with an adjustable throttle device / bypass line m , which is dimensioned so that on the one hand, after the closing process, the pressure in the compressed air accumulator / and thus the pressure of the control piston ei on the closing side drop to a desired level and on the other hand, when the closing element c is reopened, a backflow of pressure medium from the closing side of the control piston d is permitted by the overpressure prevailing in the working chamber and on the right side of the control piston when the pump a is restarted. Both the speed of the pressure reduction and the pressure medium return flow can be set manually as required by the throttle element / bypass line m.

In the embodiment of the centrifugal pump system shown in Fig. 3, the arrangement is such that the control device d and the closure member c are combined in such a way that the closure member simultaneously represents the piston for the control device. The control device is also connected on one side of the control piston to the working chamber of the pump α and on the generally other side of the control piston through the connecting line / to the pressure pipe b .

den, wherein a compressed air accumulator i with an upstream check valve and bypass line for this check valve is switched on into the line f. The two sides of the control piston are connected by lines η to a control device, not shown, through which the control piston or the closing element also independent of the processes in the working chamber of the pump and in the pressure pipe z. B. can be opened and closed by hand.

In Fig. 4 an embodiment is shown with built-in rotary valve c in the pressure tube b as a closure member, which differs from the embodiment according to Fig. 2 only by the setting device acting on the rotary valve or the closure organ '. The control device d has two adjusting pistons, on the connecting rod of which the adjusting lever of the rotary slide valve c is articulated. Otherwise, the connection of the control device to the working space of the pump α or to the pressure pipe b is the same as in Fig. 2.

In Fig. 5 the control piston d is used to control a wedge valve c built into the pressure pipe b . The cylinder side of the control piston d connected to the pressure line b is itself designed as a compressed air accumulator i , while the opening side, ie the lower side, is connected through a line e to the pressure side of an additional pump impeller J in the working chamber of the pump α . The additional pump impeller J generates and maintains a higher pressure on the lower side of the control piston than in the pressure pipe b during normal operation. The compressed air accumulator i is connected to the point g of the pressure pipe via a connecting line f with a check valve k and a throttled bypass line m , as shown in Fig. 2.

The control described can also be used for other types of closure organs, z. B. for ball slide, needle slide, pressure outlet slide and the like. B. in large systems for controlling an outlet element or a closing element arranged in a bypass line Are used in which in the main line an acting independently of the servomotor Non-return valve can be arranged. As a pressure accumulator, instead of a compressed air accumulator with a liquid filling Of course, a weight accumulator, spring accumulator or the like can also be used, which still offer the advantage that ' there is no need to temporarily replenish the liquid filling.

Claims (6)

Patent claims: 1. Centrifugal pump system with a closing element on the pressure side, characterized by a control piston (d) for the closing element (c), one side of which is connected to the working chamber of the pump (α) and the other side of which is connected to the pressure line (b) . 2. Installation according to claim 1, characterized in that a compressed air accumulator (i) is switched on in the connecting line (/) leading from the pressure line (b) to the control piston (d). 3. Installation according to claims 1 and 2, characterized in that a check valve (k) is installed in the connecting line (f) leading from the pressure line (b) to the compressed air accumulator (i). 4. Plant according to claims 1 to 3, characterized in that the check valve (k) has a bypass line (m) connected in parallel. 5. Installation according to claims 1 to 4, characterized in that an adjustable throttle element (/) is provided in the bypass line (m). 6. Plant according to claim 1, characterized in that the cylinder side of the control piston (d) connected to the pressure line (b) is itself designed as a compressed air accumulator (i) . 1 sheet of drawings