RU2285154C1 - Disk pump - Google Patents

Abstract

FIELD: handling liquids containing large solid inclusions.

SUBSTANCE: proposed disk pump has drive disk to which driven disks with central holes are secured by means of rods. Disks are provided with magnetic elements which are so located that they are directed towards each other by similar poles in each inter-disk gap. Driven disks are movable along rods.

EFFECT: enhanced efficiency due to possibility of passing large solid inclusions with no reduction in pressure head.

2 dwg

Description

The invention is intended for moving fluid and can be used in various industries for moving fluid, including containing large solid inclusions.

A well-known disk pump, consisting of a wheel housed in a casing made of several thin discs fastened to each other along the periphery, between which there are small gaps for the passage of fluid, and a discharge device (V.I. Misyura, B.V. Ovsyannikov, V.F. . Prisnyakov. Disk pumps. - M.: Mechanical Engineering, 1986, p.3-4). The design of this disk pump allows for a high head, but excludes the possibility of large inclusions passing through the pump, which is a drawback.

The prototype of the proposed disk pump is a pump for pumping liquids with solid inclusions of large sizes (US patent No. 4335994). A drive disk is attached to the drive shaft of the pump, to which driven discs with central holes are attached using rods. The gaps between the discs are provided by the distance bushings, and the discs are mounted so that narrow gaps alternate with wide ones. The size of the wide gaps should correspond to the size of solid inclusions in the liquid.

The disadvantage of this pump is the low pressure, since the installation of disks with wide gaps occurs due to the reduction in the number of disks.

The objective of the invention is to increase the efficiency of the pump due to the ability to pass large solid inclusions without reducing the pressure.

The task is achieved in that the disks are equipped with magnetic elements, which are located so that in each interdisk gap the magnetic elements belonging to adjacent disks are facing each other with the same poles, and the driven disks are mounted with the possibility of movement along the rods.

The essence of the proposed solution is illustrated by the drawing, which shows the design of the disk pump (Figure 1).

The disk pump consists of a housing 1, equipped with a fitting 2 for supplying fluid and a fitting 3 for draining fluid. A drive disk 5 is fixed on the shaft 4, to which the driven discs 7 are attached by means of the rods 6. Magnetic elements 8 are mounted on the end surfaces of the adjacent disks so that in each interdisk gap the magnetic elements belonging to the adjacent disks face each other with the same poles, and driven discs are mounted to move along the rods.

The disk pump operates as follows, the fluid enters the housing 1 through the nozzle 2. When the shaft 4 rotates, the fluid located in the gaps between the disks 5 and 7 is twisted due to friction forces and the energy from the rotary disks is transferred to the fluid. The liquid is discharged from the pump through the nozzle 3. The gap between the disks is provided by magnetic elements 8 mounted on the end surfaces of adjacent disks.

In the proposed design of a disk pump containing a drive disk, to which the driven discs with central holes are mounted by means of rods, the driven disks are mounted to move along the rods, and magnetic elements are mounted on the disks in such a way that in each interdisk gap the magnetic elements belonging to adjacent disks facing each other with the same poles, and driven discs are installed with the possibility of movement along the rods.

If during the operation of the pump a particle with a size larger than the distance between the disks enters it, it is carried away by the fluid flow into one of the inter-disk gaps, where due to the possibility of moving the disks along the rods, overcoming the interaction forces of the magnetic elements, the distance between the disks increases and the particle transported to the outlet fitting (Figure 2).

After the passage of a particle under the action of the interaction forces of the magnetic elements, the disks are set to their original position.

Thus, the passage of large solid inclusions through the pump is ensured by the short-term redistribution of inter-disk gaps.

Various layouts of magnetic elements on disks are possible.

Figure 1 shows the layout of magnetic elements in which each magnetic element (except located on the extreme disks) interacts with the same poles of magnetic elements located on the left and right, forming, for example, the following chain of magnetic interactions:

It is also possible to install magnetic elements on the end surfaces of the disks:

The proposed design of the disk pump has a simple design and combines the ability to provide high pressure, as well as the ability to pump liquid with large solid inclusions.

Claims (1)

A disk pump comprising a drive disk, to which driven discs with central holes are mounted by means of rods, characterized in that the disks are provided with magnetic elements, which are arranged so that in each interdisk gap the magnetic elements belonging to adjacent disks face each other with the same poles, and driven discs are mounted to move along the rods.

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