EP0045483A2 - Self-priming rotary pump, particularly for bringing liquids to their boiling point - Google Patents

Abstract

The invention relates to a centrifugal pump having a first centrifugal pump stage (2), which is located on the suction side and is not self-priming, and having a pump inlet nozzle (6), which is located axially at the level of the horizontal shaft (1), and having at least one centrifugal pump stage (3). which is located downstream and which, operating with the aid of auxiliary liquid, is self-priming. According to the invention, the self-priming capability and reliability of the pump, in particular for conveying media in the vicinity of their boiling point, are improved by arranging a liquid reservoir (13), of sufficient size, between two pump stages, the connection from this reservoir to the preceding centrifugal pump stage being located in the geodetically upper portion of the reservoir, and a seal (16) for closing the shaft clearance being located between the liquid reservoir (13) and the preceding centrifugal pump stage.

Description

The invention relates to a centrifugal pump with a first normal-suction centrifugal pump stage arranged on the suction side, a pump suction nozzle lying axially at shaft height and at least one downstream self-priming centrifugal pump stage working with auxiliary liquid.

Pumps of this type are known, in particular for conveying media close to their boiling point, for example liquid gases, where any flow loss on the pump suction side must be avoided in order to prevent cavitation in the first pump stage. The suction port lying axially at the level of the shaft is intended to avoid sharp diversions of the inflowing medium inside the pump before the first stage. Starting from the suction port, the suction should Line are also led without major changes in direction to the container or tank to be pumped empty, in order to keep the flow losses in the feed line as low as possible.

Until now, these pumps were usually installed so that they were installed geodetically under the container to be emptied, i.e. that they could always work with an inlet, there was no need to attach particular importance to the self-priming and waste safety of this pump. Only the liquid components that gas out under unfavorable operating conditions on the pump suction side had to be able to be sucked off and conveyed through the self-priming gyro stage or stages.

As a result of stricter safety regulations, however, people are now frequently moving underground to store the tanks or tanks for, for example, liquefied gases, and are faced with the need to either install a suitably long, securely encapsulated, inaccessible and structurally complex pump, or a pump in suction mode Set up above the container and then carry it out accordingly self-priming and waste-proof. The pumps known to date meet these last requirements only very poorly, since they generally run empty up to the lower edge of the suction nozzle after standstill and shutdown and the residual liquid then remaining in the pump is no longer sufficient to ensure reliable ventilation of the suction line and thus re-suction when restarting guarantee. Another requirement for the promotion, especially of liquid gases, is often the delivery of bubbles or gas-free medium. With pumps, especially if they have to work in the suction area under difficult suction conditions, an at least partial evaporation of the pumped medium in the suction area of the pump cannot be prevented, even if these pumps are optimally designed with regard to the pumping speed. Due to the pressure increase in the pump, part of the gas that is outgassed in the suction line or in the suction area of the pump is liquefied again, but for safety's sake, a gas separator must be installed downstream in such pumps to ensure that bubble-free and gas-free medium is guaranteed from the Pump is delivered.

According to the invention, the lack of sufficient self-priming and waste safety is now eliminated by arranging a liquid storage space of sufficient size between two pump stages, the connection to which is provided to the preceding centrifugal pump stage in the geodetically upper part of the storage space and wherein a seal for sealing between the liquid storage space and the preceding centrifugal pump stage the shaft gap is arranged. This ensures that when the pump stops the liquid from the pressure line through the pump and the suction line back into the suction tank or container, enough liquid is retained in the pump to enable re-suction when restarting. In the built-in liquid storage space, the liquid can only drain from the geodetically upper part up to the lower edge of the transition to the previous step. Backflow along the shaft gap is also prevented by the seal provided in this area between the liquid storage space and the preceding pump stage.

In a further embodiment of the concept of the invention, it is proposed to arrange the liquid storage space between the normal priming first stage and the first following self-priming centrifugal pump stage, whereby it is achieved that the largest possible proportion of liquid when the pump drops, i.e. when the liquid flows back from the pressure line through the pump into the suction-side container, it is retained in the pump itself, since a, albeit small, portion of liquid also remains in the self-priming gyro stages following the storage space. When the pump is switched on again, this liquid is then conveyed within a short time to the last self-priming stage, which is known to take over the priming alone and is then available to this stage as operating fluid for the priming process.

The liquid storage space between two pump stages can now also be used according to the invention for the further purposes of liquid gas separation during the conveying process, in which case it is expediently arranged between the first and the second self-priming gyro stage and a connection for in the area of the geodetically highest point of this liquid storage space provides for an extraction line. The arrangement of the liquid storage space at this point has the advantage that a large part of the liquid portion that may be outgassed on the suction side of the pump and in the suction line is already condensed again due to compression by the fully loaded stage and the first self-priming stage and only one at this point The rest of the gasified medium is contained in the flow. This residual portion of gaseous medium can then be at the highest point in the Liquid supply space provided extraction line are returned to the suction-side tank or container, so that from the stages following the liquid storage space, only gas-free liquid is conveyed and leaves the pump pressure port. A correspondingly optimally dimensioned cross-section of the line leading back from the liquid storage space to the container or tank also allows a possible proportion of liquid flowing back with the gas to be reduced to a minimum, so that the pump efficiency is only marginally or not at all influenced thereby.

In order to increase the separation effect in the liquid storage space, it is proposed to design this space as a liquid cooking separating and separating container by appropriate design and the installation of ribs. These internals also have the additional advantage that they also fall off when the pump, i.e. when the liquid flows back after switching off from the pressure line through the pump back into the suction-side container, brake the backflow of the medium and thereby retain a particularly large part of the liquid in the pump part, which is connected downstream of the liquid storage space.

Self-priming centrifugal pump stages in the form of side channel stages have proven particularly suitable for use in such a pump, since they have optimal self-priming capability. In this case, the axial extent of the liquid storage space should correspond approximately to the axial extent of a side channel step, since this retains sufficient liquid in the pump for the suction process. In order to ensure the optimal suction capacity, it is finally proposed that the suction slot of the side channel pump stage following the liquid storage space is arranged in the geodetically lower area of the liquid storage space, so that the entire liquid supply of the storage space even when the pump is started up again, the self-priming stages as auxiliary or operating liquid for the Suction process is available.

The liquid storage space is expediently connected to a device for automatically checking the liquid level in the liquid storage space, which emits a signal or prevents the pump from being started up if the liquid storage space does not contain a sufficient amount of liquid. Furthermore, it can be expedient if a time relay is provided, which switches the pump off again after it has been switched on if the suction has not taken place within a certain predetermined period of time. These measures result in securing the pump against dry running.

The invention is explained, for example, with reference to the accompanying drawings.

• 1 shows the longitudinal section through a 5-stage centrifugal pump, the liquid storage space being arranged behind the first normal-suction centrifugal pump stage.
• FIG. 2 also shows the longitudinal section through a 5-stage centrifugal pump, in which, however, the liquid storage space is arranged behind the first self-priming centrifugal pump stage.
• 3 shows a perspective illustration of the pump arrangement.

In the figures, the pump shaft is denoted by 1 and carries the fully loaded normal-suction rotary impeller 2 in the first pump stage, which is specially designed for optimal pumping speed, i.e. is designed for the lowest possible NPSH value of the pump, without placing particular value on the efficiency and delivery head of this first wheel. With 3 the impellers of the following side channel stages are designated. 4 is the pump suction housing with the suction port 5 and the inlet 6 arranged axially at shaft height. The pump housing of the standard suction stage is designated 7, the housing parts of the following side channel pump stages are 8 and 9. The pressure port 11 is located on the pump pressure housing 10 the pressure housing 10 still follows the mechanical seal or seal housing 12.

In FIG. 1, behind the first fully loaded centrifugal pump stage, the liquid storage space 13 is provided, the transition to the first fully loaded centrifugal pump stage being arranged in the geodetically upper region of the liquid storage space, above the partition 14, which separates the liquid storage space from the first fully loaded centrifugal pump stage. Furthermore, between the housing part 15 forming the first storage space in the area of the shaft between this housing part and shaft 1, shaft seal 16 is provided, which prevents liquid in the area of the hub from passing from the liquid storage space or the pump stages that have been resettled into the first pump stage.

2, the liquid storage space 13 is arranged behind the first self-priming and in front of the second self-priming side-channel centrifugal pump stage, the connection from the fluid storage space to the preceding centrifugal pump stage again takes place in the geodetically upper area of the liquid storage space, above the partition 14, while between the shaft and the hub part of the housing 15 again a shaft seal 16 is arranged. In addition, 13 ribs 17 are provided in the liquid storage space, which are intended to bring about a separation between gas and liquid in the storage space, a removal opening 18 being additionally arranged at the geodetically highest point of the storage space; for returning the gas components located in space 13 into the suction-side container or tank from which the pump draws in. In both examples, the self-priming pump stages are designed as side channel centrifugal pumps and the suction slot 19 of the side channel stage following the liquid storage space can be seen in the geodetically lowest point of the liquid storage space.

It should also be mentioned that the pump shaft is supported in a slide bearing 20 and a ball bearing 21.

3 shows the pump on the base plate 22 with the intake port 6, the housing part 7 of the first pump stage, the housing part 15 of the liquid storage space and the housing parts 8 and 9 of the following self-priming stage. The pump is driven by an electric motor 23. To the upper or lower part of the housing part 15 of the liquid storage space, a device 26 for determining the liquid level in the liquid storage space is connected via connections 24, 25, the electrical energy of which is supplied by a battery 27. Such devices for determining the liquid level are known and therefore do not need to be explained here tion. The device is set so that it emits a signal when, when the pump is switched on, the liquid level in the liquid storage space is below a certain limit which must be reached if the liquid contained in the liquid storage space is to be sufficient for the suction process. When this signal appears, the pump motor 23 is either prevented from running automatically and / or the operator is made aware of the insufficient fluid level in the pump so that it can provide a refill.

In addition, the device 26 is set up in such a way that when a certain period of time has elapsed - for example 30 seconds - after the pump has started up, it is checked whether the pump has sucked in. If the suction has not taken place, the pump is switched off automatically.

The same applies if the pump drops during operation, i.e. no liquid is sucked in.

Claims (8)

1. Centrifugal pump with a first standard suction centrifugal pump stage arranged on the suction side, a pump suction nozzle lying axially at the level of the horizontal shaft and at least one resettled self-priming centrifugal pump stage working with auxiliary liquid, characterized in that a liquid reservoir of sufficient size is arranged between two pump stages, the connection to the preceding centrifugal pump stage in the is arranged geodetically upper part of the storage space and wherein a seal for sealing the shaft gap is arranged between the liquid storage space and the preceding centrifugal pump stage. 2. Centrifugal pump according to claim 1, characterized in that the liquid reservoir is arranged between the normal suction first stage and the following first self-priming centrifugal pump stage. 3. Centrifugal pump according to claim 1, characterized in that the liquid storage space between the first and the second self-priming stage and that in the region of the geodetically highest point of the liquid storage space a connection for a sampling line is arranged. 4. Centrifugal pump according to claim 1 to 3, characterized in that the liquid storage space is formed by appropriate design and the installation of fins as a liquid / gas separating or separating container. 5. Centrifugal pump according to claim 1 to 4, characterized in that the self-priming centrifugal pump stages are designed as side channel stages and the axial extent of the liquid storage space corresponds approximately to the axial extent of a side channel stage. 6. Centrifugal pump according to claim 5, characterized in that the suction slot, the side channel pump stage following the liquid storage space is arranged in the geodetically lower region of the liquid storage space. 7. Centrifugal pump according to one of claims 1 to 6, characterized in that the liquid storage space is connected to a device for determining the liquid level in the liquid storage space, which is set up to emit a signal when the liquid level in the liquid storage space falls below a predetermined level. 8. Centrifugal pump according to one of claims 1 to 7, characterized in that the pump is connected to a device for determining the liquid filling in the liquid storage space, which is set up to emit a signal when the pump has not sucked in within a predetermined time interval.

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