DE7710130U1 - SUBMERSIBLE PUMP FOR RADIOACTIVE LIQUIDS - Google Patents

Description

The innovation concerns a submersible pump for radioactive liquids, from a pump part immersed in the pumped medium with a permanent magnet driven impeller as well as Fluid conduction, bearing, sealing and coupling systems and a drive part with pump lantern and motor located outside the pumped medium, which connects to the pump part over a long period of time Shaft and a conveyor pipe is connected, consists.

In the years to come, storage tanks for treatment will be used around the world and interim storage of radioactive liquids and solutions. These tanks must be used to shield the radioactive radiation must be mounted in thick-walled concrete cells. Usually several T.inks are grouped together in one warehouse and via a pipe system laid in a pipe duct for shielding, with one another and with a filling and removal station connected. Because of the high level of radiation, it is impossible, for example, to carry out repair work on the storage tank cells once the storage tanks have been infested to enter. Repair and maintenance work in the pipe channel can only be carried out after the pipes have been thoroughly flushed and fittings are carried out. The tanks must be ready for operation, filled and emptied, in particular the tanks must be able to be emptied safely at any time so that the contents of the tank can be stored in the event of a leak can be quickly transferred to a reserve tank.

In the case of the storage tanks carried out so far, geodetic ones result Delivery heights of over IO meters and operating temperatures of up to 60 ° C must be taken into account, which means that self-priming Centrifugal pumps above the concrete cell excluded will.

7710130 08/18/77

For the promotion of radioactive solutions in nuclear technology generally steam jet pumps and airlift devices have become well proven. However, steam jet pumps have the disadvantage that the pumped medium is heated by the motive steam and the amount to be stored increases by the motive steam condensate. Because of Despite their reliability and simplicity, steam jets are still of the aforementioned disadvantages used as safety funding organs. Airlift facilities are not very suitable for large conveying capacities and could only with the present level of conveyance Vacuum support can be operated. Airlifts also have the disadvantage that radioactive waste air is generated in large quantities. The use of compact submersible pumps, in which the drive motor is also immersed in the pumped medium, is an advantage ier necessary radiation resistance of the seals and electrical Insulating materials to considerable difficulties.

A pot pump is also known which is lowered into the tank to just above the maximum liquid level. This Pot pump consists of a self-priming pump with a compactly attached liquid reservoir. But this pot pump has the Disadvantage that liquid always has to be presented before commissioning. Furthermore, this type of pump and the present possible operating conditions of 60 C at a suction height <6 m, safe suction of the pumped medium is no longer guaranteed.

■ It was therefore the task of the present innovation to provide a pump create the pump impeller as deep as possible in the storage tank is arranged so that the suction height is practically zero, which as possible without filling up with liquid or running against it closed slide can start the conveying operation, too

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when the slide valve in the pressure line is closed, incorrect operation cannot damage the pumped medium is similarly well encapsulated to the outside as in the known canned motor drives, which are through an installation opening that is as small as possible can be drained into the storage tank, the maintenance of which are gentle parts in the shielded area if possible must be accessible and which can be assembled and disassembled extremely quickly from the pipe duct.

This object was achieved by using a submersible pump, which consists of a pump part immersed in the delivery medium with permanent magnetic driven impeller as well as fluid conduction, bearing, sealing and coupling systems and one outside the There is a drive part with pump lantern and motor located behind shielding devices, the drive part with the pump part via a long drive shaft Conveyor pipe and a lubricant pipe is connected and according to the innovation the pressure delivery pipe, the lubricant pipe and the drive shaft pipe including drive shaft and circulation-lubricated bearings through the use of common I-flanges several assembly units form and the shaft sections are designed to be plugged in these assembly units via spline couplings.

These assembly units have a length of, for example, 0.5 up to 2 m and can therefore in the event of damage or leaks after lifting the submersible pump can be exchanged easily and in particular very quickly, which is also due to the new multi-wedge coupling is particularly encouraged, especially if the inlets of the wedge ends and keyways of these advantageously Coupling are chamfered and tapered to a point.

7710130 08/18/77

An exemplary embodiment is shown in Figures I to III

management form of the submersible pump according to the innovation explained in more detail, i

where Figure I is a schematic longitudinal section through a \

Tank farm and the submersible pump, Figure II details of the f

Submersible pump on an enlarged scale and Figure III a |

Splined shaft coupling shows. _s I

i The figures show schematically a renewal according dip 'pump, from a radiation outside the active region
on ei * i.ar lantern (l) through the shielding plates (2); protrudes through-mounted motor (3), "tight encapsulated over a long ■ in a tube (4) against the medium to be conveyed (5), and '. mounted drive shaft (6) in the conveying medium immersing
Impeller (7) driven by a permanent magnet coupling (β)
and the pressure delivery pipe (9} _, the lubricant pipe (lO)
and the drive shaft tube (h) with the help of common connections

bindungsflanschen (II) in dismountable j mounting units (17) can be decomposed rapidly, the "tfellenteil-; pieces in these assembly units (17) via Vielkeilwellen- '■ couplings (12) having specially shaped for easy insertion wedge ends (! 13) and keyways (l ') * are pluggable to;. lubrication of .ntriebswellenlager flows a small amount of _oil, from the reservoir (15) by gravity on the individual i ball bearings, wherein the incoming below oil over a fixed to the drive shaft The auxiliary impeller and the lubricant delivery line (10) are pumped back into the reservoir (15)
He (15) retains a standstill over the Λ'οτ ^ ΐβ lying outside the radiation-active area. To a penetration of
radioactive solution into the drive shaft tube (^), e.g. through
To prevent leaky flange connections, the drive shaft tube (4) can, if necessary, be pressurized with a gas pressure that is higher than the pressure of the surrounding medium (5)

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on the pipe (4). With a simple bubbler monitoring in the gas supply line, leaks can be detected in good time. The impeller bearing is lubricated by the pumped medium and chilled. The fluid-tight separation between the hydraulic pump part and the drive shaft (6) with bearings is carried out through the can of the permanent magnet coupling (8). To protect the hydraulic pump part from warming up over long periods of time If the pump is operated against closed valves in the pressure line, a small amount of the pumped medium is dispensed through a bore (l6) returned to the storage tank on the pressure side, immediately behind the impeller. Monitoring the driveshaft bearings on impermissible temperature occurs with the help of the lubricant circuit by monitoring the oil return temperature,

The force is transmitted to the hydraulic pump part via a permanent magnet coupling. The pump can therefore be designed without a stuffing box and is therefore easy to maintain. Because the pump body divided into several parts can be taken by Herai or Adding such sections also allows the installation length to be adapted to the operational conditions.

Frankfurt / Main, March 14, 1977
Dr.Br.-Bi

7710130 08/18/77

Claims (7)

SCHUT ZAN'S CHALLENGES 1. Submersible pump for radioactive liquids, consisting of a pump part immersed in the pumped medium with a permanent magnet driven impeller as well as liquid guide, bearing, sealing and coupling systems and a drive part with pump lantern and motor located outside the pumped medium, which connects to the pump part via a long shaft and a delivery pipe is connected, characterized in that the pressure delivery pipe (9) » the lubricant pipe (19) and the drive shaft pipe (4) including the drive shaft (6) and the circulation-lubricated bearing through the use of common flanges (ll) several assembly units ( 17) and the shaft sections in these assembly units (17) are designed to be pluggable via spline couplings (12). 2. submersible pump according to claim 1, characterized in that ^rt ass on the pressure side immediately behind the impeller has a bore (16) is present. 3. Submersible pump according to claims 1 and 2, characterized in that the inlets of the wedge ends (13) and keyways (Vi) of the splined shaft coupling (12) are chamfered. H. Submersible pump according to claims 1 to 3 characterized gekennzeichne _f t that the enemas of the wedge member (13) and keyways (14) leak pointed. 5. Submersible pump according to claims 1 to 4, characterized in that the drive shaft tube (h) can be pressurized via a gas connection located above the conveying medium. 7710130 08/18/77 6. Submersible pump according to claims 1 to 5, dad u rch gekennzeic hnet that there is a reservoir (15) for the lubricant outside the radiation-active area, which is attached to the drive shaft by a "Auxiliary impeller is uragepumped contamination-free. 7. submersible pump according to claims 1 to 6, d adurc gekennzeichne h t, that are incorporated in the lubricant circuit of the radiation outside the active region measuring instruments for monitoring the storage temperature. 7710130 08/18/77