ROTATING ASSEMBLY WITH INTEGRAL MAGNETIC FILTER FOR WET ROTOR CIRCULATING PUMP

Abstract

A wet rotor circulating pump implementing an integral magnetic filter for removing suspended contaminates from the water being circulated.

Claims

1. A wet rotor circulating pump implementing an integral magnetic filter for removing suspended contaminates from the water being circulated, comprising a. a rotor housing; b. a filter cover juxtaposed with respect to the rotor housing so as to form a magnet chamber therebetween, c. in combination, a rotor, a shaft, bearing, and an impeller disposed within the rotor housing, wherein a bearing race is defined by a space between the bearing and the impeller; d. a baffle disposed within the magnet chamber; e. a secondary chamber cover juxtaposed with respect to the filter cover so as to form a secondary chamber therebetween, f. a mechanical filter disposed in proximity to the secondary chamber; and g. a ring magnet disposed within the magnet chamber in proximity to the baffle; wherein the filter cover comprises i. a plurality of magnetic chamber inlet ports disposed around the outer circumference of the filter cover to allow water to enter the pump; ii. a plurality of secondary chamber inlet ports located so as to allow water to flow from the magnet chamber into the secondary chamber; and iii. a plurality of mechanical filter inlet ports located so as to allow water to flow from the secondary chamber and be filtered by the mechanical filter; whereby water having suspended contaminates flows into enter the magnetic chamber via the plurality of magnetic chamber inlet ports and flows over the ring magnet, so that the ring magnet attracts magnetic, metallic, suspended contaminants from the water as it flows thereover, then enters the secondary chamber via the plurality of secondary chamber inlet ports and flows through the secondary chamber to flow through the bearing race to lubricate the bearing/shaft interface and through the mechanical filter via the plurality of mechanical filter inlet ports so that other suspended contaminates are filtered from the water by the mechanical filter, such that the water that lubricates the bearings and exits the pump has been magnetically and mechanically filtered of suspended contaminants.

2. A method for a wet rotor circulating pump implementing an integral magnetic filter for removing suspended contaminates from the water being circulated, comprising the steps of: a. causing water, having suspended contaminates, to enter a magnetic chamber via a plurality of magnetic chamber inlet ports; b. causing the water in the magnetic chamber to flow over a ring magnet, whereby the ring magnet attracts metallic suspended contaminates from the water as it flows thereover; c. causing the water to enter a secondary chamber via a plurality of secondary chamber inlet ports; d. causing a first portion of the water flowing through the secondary chamber to flow through a bearing race and lubricate a bearing/shaft interface; e. causing a second portion of the water flowing through the secondary chamber to flow through a mechanical filter via a plurality of mechanical filter inlet ports whereby other suspended contaminates are filtered from the water by the mechanical filter; whereby the water that exits the pump has been magnetically and mechanically filtered of suspended contaminates.

Description

BRIEF DESCRIPTION OF THE DRAWING

[0011] FIG. 1 is a cross-sectional view of a preferred embodiment water circulation pump of the present invention, which also illustrates the flow path of water through the pump.

[0012] FIG. 2 illustrates the removable rotating element of the preferred embodiment pump of FIG. 1.

[0013] FIG. 3 illustrates the magnetic base of the preferred embodiment pump of FIG. 1.

[0014] FIG. 4 is a flowchart depicting the flow of water through the preferred embodiment pump of FIG. 1

DETAILED DESCRIPTION OF THE INVENTION

[0015] Shown in FIG. 1 is a cross-sectional view of a preferred embodiment water circulation pump of the present invention, which also illustrates via the set of arrows the flow path of water through the pump (see also FIG. 4). The preferred embodiment as shown in FIG. 1 includes a rotor housing 16 detachably attached to a removable rotating element as shown in FIG. 2. The removable rotating element includes a rotor 2 and shaft 3 attached to an impeller 4. A bearing 6 and a bearing and filter support cover, generally indicated by the numeral 20, is juxtaposed with respect to the impeller 4, including a bearing race 18 as shown in FIG. 1, through which lubricating water flows. An annular magnetic and filter flow chamber 17 is defined by the separation between the rotor housing flange 16 and the bearing and filter flange 20 as shown. A ring magnet 1 is disposed within the magnetic chamber 17, and a baffle 14 integral with the housing 16 is disposed so as redirect the water flow to ensure it flows in close proximity to all three exposed sides of the ring magnet 1.

[0016] As also shown in FIG. 3, a plurality of magnetic chamber inlet ports 11 are disposed around the outer circumference of the filter cover 20 to allow water to enter the pump as will be further described below.

[0017] A magnetic shield 13 is provided juxtaposed between the ring magnet 1 and the bearing and filter flange 20 to weaken the magnetic field outside of the magnet chamber 17, thusly preventing the buildup of magnetic particulates outside of the chamber.

[0018] A central, secondary flow chamber 10 is defined by the juxtaposition of the filter flange 20 and a secondary chamber cover 8 as shown in FIG. 2. As shown in particular in FIG. 3, a plurality of secondary chamber inlet ports 12 are located so as to allow water to flow from the magnetic chamber 17 into the secondary chamber 10 as will be further described below.

[0019] As further shown in FIG. 3, a plurality of mechanical filter inlet ports 9 are disposed around the inner circumference of the filter flange 20 to filter the water via mechanical filter (e.g. sintered metal) as it flows from the secondary chamber 10 as will be further described below. Also shown in FIG. 3 are magnetic shield/locator 19, mechanical filter support 20, and front bearing support 21.

[0020] Referring to the flowchart of FIG. 4, and as illustrated by the arrows in FIG. 1, water with metallic and non-metallic particulate enters the magnet chamber 17 at step 402 through the magnet chamber inlet ports 11 and flows over the high strength ring magnet 1 at step 404. The baffle 14 redirects the water flows to ensure it flows in close proximity to all three exposed sides of the ring magnet 1.

[0021] As a result, the water flowing in close proximity to and past the ring magnet 1 is now mostly devoid at step 406 of metallic particulate. The water then enters, at step 408, the secondary chamber 10 through the secondary chamber inlet ports 12, where at step 410 it provides lubrication to the bearing/shaft interface through the bearing race 18 which is sized to allow water but not large non-metallic particulate matter that can damage the bearings. At step 412, water also enters the rotor housing 16 through the mechanical filter inlet ports 9, and at step 414 any remaining particles are filtered from the water by the mechanical filter 5. The filtered water then exits at step 416 upon expansion and contraction of the water as the pump starts and stops.

[0022] As shown in FIG. 2, the rotating element is removable from the rotor can 16 for cleaning and clearing away of excessive buildup of magnetic particulates.

[0023] Comparative benefits and advantages of the present invention include: [0024] Compact, one pump replaces a pump and external magnetic filter [0025] Fewer mechanical connections, reducing the opportunity for leak [0026] Reduction in installation costs, component costs, system operating costs, and maintenance costs [0027] Extends the life of the pump and the central heating system [0028] Maintains overall system efficiency.