Cutting system for a grinding pump and related grinding pump

Abstract

A cutting system for a grinding pump, including a cutting disc attached to the pump near an inlet and having a cutting surface with multiple cutting orifices, and a rotating cutter attached to the rotating shaft of the pump and having two cutting blades, each blade having a cutting edge on a forward-facing side of the rotating cutter. The rotating cutter is located on the upstream side of the cutting disc, and cooperates with the cutting orifices of the cutting disc to perform cutting actions. Each cutting orifice has a hole extending from the cutting surface through the cutting disc to form a feeding orifice, and a cutting protrusion protruding from the cutting surface and surrounding the hole region. The multiple cutting orifices define recessed areas of the cutting surface between the cutting orifices. The cutting system can prevent uncut floating matters from being trapped, and is effective and safe.

Claims

1. A cutting system for a grinding pump, the cutting system comprising: a cutting disc configured to be attached to the grinding pump near an inlet of the grinding pump, wherein the cutting disc includes a cutting surface, and the cutting surface has a plurality of cutting orifices; and a rotating cutter configured to be attached to the grinding pump via a rotating shaft of the grinding pump, wherein the rotating cutter includes at least two cutting blades, each cutting blade having a cutting edge on a forward-facing side in a direction of rotation of the rotating cutter, the rotating cutter being located on an upstream side of the cutting disc, wherein each cutting edge is configured to cooperate with the plurality of cutting orifices to perform a cutting action when the rotating cutter rotates; wherein each cutting orifice has a hole region extending from the cutting surface through the cutting disc to form a feeding orifice, and has a cutting protrusion that protrudes from the cutting surface, the cutting protrusion surrounding the hole region, wherein the plurality of cutting orifices define at least one recessed area of the cutting surface between at least two of the cutting orifices, and wherein the cutting protrusion of each cutting orifice is a ring-shaped structure that includes an inner cutting edge on an inner side of the ring-shaped structure and an outer cutting edge on an outer side of the ring-shaped structure.

2. The cutting system of claim 1, wherein the cutting orifices are arranged on the cutting disc in a radial direction and distributed in a circumferential direction with respect to a rotation axis of the rotating shaft.

3. The cutting system of claim 1, wherein the ring-shaped structure of the cutting protrusion of each cutting orifice either has at least one gap, or is a closed ring without any gaps.

4. The cutting system of claim 1, wherein the cutting disc includes a plurality of cutting groups, each cutting group including at least two of the plurality of cutting orifices, and wherein the plurality of cutting groups are arranged on the cutting disc in a radial direction and distributed in a circumferential direction with respect to a rotation axis of the rotating shaft.

5. The cutting system of claim 4, wherein at least one cutting group of the plurality of cutting groups further includes at least one cutting tip configured to connect the at least two cutting orifices of the cutting group, the cutting tip having a cutting tip edge connected to cutting edges of the cutting orifices.

6. The cutting system of claim 5, wherein the cutting tip edge faces against the direction of rotation of the rotating cutter.

7. The cutting system of claim 1, wherein the cutting disc further includes a plurality of cutting blocks distributed between the cutting orifices, wherein each cutting block has a cutting edge facing against the direction of rotation of the rotating cutter.

8. The cutting system of claim 1, wherein the cutting surface further includes a plurality of diversion ribs which are either connected to or separated from the cutting orifices, wherein the diversion ribs are distributed in a circumferential direction around a rotation axis of the rotating shaft.

9. The cutting system of claim 8, wherein each diversion rib has a linear shape and extends in a radial direction of the cutting disc.

10. The cutting system of claim 1, wherein the at least one recessed area is located on at least one plane.

11. A grinding pump comprising the cutting system of claim 1, the grinding pump further comprising a pump body having the inlet and an outlet, wherein the rotating shaft is disposed within the pump body, wherein the cutting disc is fixedly connected to the pump body and covers the inlet, wherein the rotating cutter is fixedly connected to the rotating shaft and is driven by the rotating shaft, whereby the cutting edges of the rotating cutter cooperate with the plurality of cutting orifices to perform cutting actions when the rotating cutter rotates.

12. The cutting system of claim 8, wherein each diversion rib has a curved shape, and a tangential direction of the curved shape is parallel to the direction of rotation of the rotating cutter.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Preferred embodiments of the present invention are described with reference to the drawings. In these drawings, like reference symbols represent like features.

(2) FIG. 1 is a cross-sectional view showing a grinding pump according to an embodiment of the present invention.

(3) FIG. 2 is a exploded view of a cutting system for a grinding pump according to an embodiment of the present invention.

(4) FIG. 3 is another exploded view of the cutting system shown in FIG. 2.

(5) FIG. 4a shows an exemplary cutting group of the cutting disc of FIG. 3 according to one embodiment of the present invention.

(6) FIG. 4b shows an exemplary cutting group of the cutting disc of FIG. 3 according to another embodiment of the present invention.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

(7) Preferred embodiments of the present and their applications are described below. It should be understood that these descriptions describe embodiments of the present invention but do not limit the scope of the invention. When describing the various components, directional terms such as “up,” “down,” “top,” “bottom” etc. are not absolute but are relative. These terms may correspond to the views in the various illustrations, and can change when the views or the relative positions of the components change.

(8) In this disclosure, terms such as “connect”, “couple”, “link” etc. should be understood broadly; for example, they may be fixed connections, or removable or detachable connections, or integrally connected or integrally formed; they may be directly connected, or indirectly connected via intermediate parts. Those skilled in the relevant art can readily understand the meaning of these terms as used in this disclosure based on the specific description and context. Referring to FIG. 1, the grinding pump 10 includes a pump body 11 having an inlet 14 and an outlet 15. A rotating shaft 12 is disposed within the pump body 11. An impeller 13 is disposed within a chamber defined by the pump body 11, and is supported by and driven to rotate by the rotating shaft 12, so that a liquid is transported from the inlet 14 on the suction side or upstream side to the outlet 15 on the discharge side or downstream side. Typically, a cutting system 20 of the grinding pump 10 is disposed at or near the inlet 14, and includes a cutting disc 21 and a rotating cutter 22 that cooperate with each other. The cutting disc 21 is fixedly connected to the pump body 11, for example, by threaded fasteners, and covers the inlet 14. The cutting disc 21 has a number of cutting orifices 30, which serve as feeding orifices with a filtering function. The rotating cutter 22 is fixedly connected, for example, by threaded fasteners, to the rotating shaft 12 on the upstream side of the cutting disc 21. Thus, the rotating cutter 22 rotates with the rotating shaft 12 and cooperates with the cutting disc 21 to cut the floating matters that enters the feeding orifices, to reduce the sizes of the floating matters in the liquid (e.g. wastewater) so that they can readily enter the pump.

(9) It should be understood that while the descriptions below use a pump for wastewater as an example of a grinding pump, the grinding pump may also be, without limitation, any water pump, vacuum cleaner, suction filter, etc. that has a cutting function.

(10) According to embodiments of the present invention, gaps in the axial direction (the direction parallel to the rotating shaft) is provided between the cutting disc and the rotating cutter of the cutting system, which can allow the floating matters to be sufficiently cut so they can smoothly enter the pump body. Such axial gaps can be realized without requiring additional components, and do not adversely affect the normal cutting operation.

(11) More specifically, referring to FIGS. 2 and 3, the cutting system according to an embodiment of the present invention includes a cutting disc 21 and a rotating cutter 22. The cutting disc 21 is adapted to be affixed to the pump body 11 near the inlet 14, and has a cutting surface 211. The cutting surface 211 has a series of cutting orifices 30 with cutting edges. The rotating cutter 22 is adapted to be affixed to the rotating shaft 12 (not shown in FIGS. 2 and 3) of the grinding pump, which extends through a central opening 213 of the cutting disc 21, so as to be rotationally coupled to the grinding pump 10. The rotating cutter 22 has at least two cutting blades 221 that extend in a substantially radial direction of the rotation axis. The illustrated embodiment shows two cutting blades, but there may be three, four, or other number of cutting blades. Each cutting blades 221 has a cutting edge 222 on the forward-facing side in the direction of rotation (counter-clockwise in this example, as shown by the arrow in FIG. 3). When the rotating cutter 22 is driven by the rotating shaft 12 to rotate, the cutting edges 222 cooperate with the cutting orifices 30 of the cutting disc 21 to cut the floating matters.

(12) Referring to FIGS. 4a and 4b, in some embodiments, each cutting orifice 30 of the cutting disc 21 includes a hole region 31 extending from the cutting surface 211 through the cutting disc 21, to form a feeding orifice. In some embodiments, the cross-sectional size of the hole region 31 is constant in the axial direction of the hole, or the size may increase or decrease in the feeding direction of the materials. Also, while the hole regions 31 shown in the drawings have a round cross-section, they may alternatively have any other suitable cross-sectional shapes, such as oval, triangular, square, rectangular, regular or non-regular polygons, etc. In various embodiments, the multiple cutting orifices 30 may have the same or different sizes, and the same or different cross-sectional shapes.

(13) Each cutting orifice 30 beneficially includes a cutting protrusion 38 that protrudes from the cutting surface 211 and surrounds the hole region 31. Correspondingly, the areas of the cutting surface 211 not occupied by the cutting orifices 30 (the cutting protrusions 38) constitute recessed areas 212 which are recessed as compared to the protruded surface of the cutting protrusions 38, as shown in FIG. 3. Preferably, all cutting protrusions 38 protrude by the same distance and have flat top surfaces. Depending on nature of the liquid being transported and the floating matters in the liquid, the protruding distance of the cutting protrusions 38 from the cutting surface 211 may be chosen based on practical need. This defines the recessed depth of the recessed areas 212 (i.e., the axial gap). The axial position of the cutting edges 222 of the rotating cutter 22 is adjusted to be at the same plane as the top surfaces of the cutting protrusions 38. Preferably, the recessed areas 212 are on the same plane. In some alternative embodiments, the axial gap between the top surface of the cutting protrusions 38 and the cutting surface 211 may have different values, forming multiple levels of recessed regions, which can provide a multi-level cutting effect.

(14) In these embodiments, during operation, the recessed areas 212 provide a space for the floating matters to move around near the cutting surfaces, so that they will not become stuck between the rotating cutter 22 and the cutting disc 21 and will not cause the rotating cutter 22 or rotating shaft 12 to be stuck. This can ensure successful transportation of the floating matters. Because the recessed areas 212 are present only between the different cutting orifices 30, they will not adversely affect the cutting operation of the cutting orifices 30 and rotating cutter 22, so that the floating matters can be successfully cut.

(15) In some embodiments, the multiple cutting orifices 30 are independent of each other and are arranged on the cutting disc 21 in the radial direction and distributed in the circumferential direction with respect to the rotating axis of the rotating shaft 12. For example, the distribution may be a substantially uniformly spaced radial and/or circumferential distribution, or a regular but non-uniformly spaced radial and/or circumferential distribution, etc.

(16) Beneficially, the cutting orifices 30 are arranged on the cutting disc 21 in both the radial direction and distributed in the circumferential direction with respect to the axis of the rotating shaft 12. In some embodiments, the cutting disc 21 includes multiple cutting groups 36, each cutting group 36 including at least two cutting orifices 30, as shown in FIG. 3. The multiple cutting groups 36 are arranged on the cutting disc 21 in the radial direction and distributed in the circumferential direction with respect to the rotation axis of the rotating shaft 12. The multiple cutting groups 36 may also be disposed in different orientations, so that the multiple cutting orifices 30 are distributed on the cutting surface 211 in a staggered layout. This way, the cutting orifices 30 can cover substantially the entire cutting range of the rotating cutter 22, making the cutting operation more efficient.

(17) In some embodiments, the cutting protrusion 38 of the cutting orifice 30 may be a ring shaped structure, and include an inner cutting edge 32 on the inner side of the ring shaped structure and an outer cutting edge 33 on the outer side of the ring shaped structure, as shown in FIGS. 4a and 4b. It should be understood that the ring shape here refers to a shape formed by a band that surrounds the hole; they are not required to be round, and may alternatively have a shape that is triangular, square, rectangular, oval, regular or non-regular polygonal, etc.

(18) By providing the dual inner and outer cutting edges, the cutting orifices 30 achieve multiple cutting actions in their interactions with the rotating cutter 22. Since the floating matters in the liquid, under the suction pressure of the pump, have to enter the pump body 11 via the hole regions 31 of the cutting orifices 30, they will be cut into sufficiently small particles under the multiple cutting actions, so that they can enter and exit the pump body smoothly and unimpeded.

(19) In the embodiment shown in FIG. 4a, the ring shaped structure of the cutting protrusion 38 has at least one gap 37 in the ring, which can help the small particles produced by the cutting action enter the pump body. In the embodiment shown in FIG. 4b, the ring shaped structure of the cutting protrusion 38 is a closed ring without any gaps.

(20) FIG. 4a shows an exemplary cutting group 36a, where the two cutting orifices 30 are connected together by at least one cutting tip 34 (one is shown). The cutting tip is a protrusion from the cutting surface 211 ending at the same height level as the protrusions 38 of the cutting orifices 30. The edges of the cutting tip 34 form a pointed cutting tip edge 34a which is connected to the cutting edges of the cutting orifices. For example, in the case where the ring shaped structures 38 have gaps 37, as shown in FIG. 4a, the cutting tip edges 34a pass through the gap to be connected to the inner cutting edges 32 of the cutting orifices 30. Beneficially, the cutting tip edges 34a and their tip generally face against the forward moving direction of the rotating cutter 22 (refer to FIG. 3). As shown in FIG. 4a, in some embodiments, the cutting disc 21 may further include cutting blocks 35 distributed between the cutting orifices 30. The cutting blocks 35 are protrusions from the cutting surface 211 ending at the same height level as the protrusions 38 of the cutting orifices 30. Each cutting block 35 has cutting edges 35a, where the cutting edges 35a and their pointed tip generally face against the forward moving direction of the rotating cutter 22. The cutting tips 34 and cutting blocks 35 provide further cutting actions for cutting the floating matters. Although they are shown as having triangular shapes, other shapes may also be used.

(21) In the exemplary cutting group 36b shown in FIG. 4b, the ring shaped structures of the cutting protrusion 38 are closed rings. In this case, the cutting tip edge 34b of the cutting tip 34 are connected to the outer cutting edges 33 of the cutting orifices 30.

(22) In some embodiments, as shown in FIG. 3, the cutting surface 211 of the cutting disc 21 further includes multiple diversion ribs 40, which may be connected to or separated from the cutting orifices 30. The diversion ribs 40 are protrusions from the cutting surface 211, and are distributed in the circumferential direction around the rotation axis of the rotating shaft 12. Similar to the distribution of the cutting orifices 30, the multiple diversion ribs 40 may be arranged in the radial direction of the cutting disc 21. The diversion ribs 40 may have curved or linear shapes extending in a radial direction. For a curved shape, the tangential direction of the curve may be substantially parallel to the moving direction of the cutting edge 222 of the rotating cutter 22.

(23) Using the cutting orifices, including individual cutting orifices, grouped cutting orifices, connected cutting orifices, or cutting orifices in combination with diversion ribs, embodiments of the present invention solve the low cutting efficiency problem and pump entrance blockage problem of conventional technologies. More specifically, referring to FIGS. 1-3, when the grinding pump 10 is operation, the impeller 13 of the pump body 11 is driven by the rotating shaft 12 to rotate; the liquid such as wastewater enters the pump body 11 from the cutting orifices 30 of the cutting system 20 under the suction pressure, and enters the pump inlet 14. When the floating matters in the liquid pass in the vicinity of the cutting orifices 30, the rotating cutter 22, which rotates with the rotating shaft 12, performs cutting operations with the cutting disc 21. Thus, larger particles in the liquid are cut and shredded into smaller particles, so that the smaller particles can enter the pump body 11 from the cutting orifices 30 along with the liquid. Further, the impeller 13 drives the wastewater to exit the outlet 15. The cutting system 20 improves the cutting effectiveness and the pumping effectiveness.

(24) It should be understood that the embodiments shown in the drawings only illustrate the preferred shapes, sizes and spatial arrangements of the various components of the grinding pump and its cutting system. These illustrations do not limit the scope of the invention; other shapes, sizes and spatial arrangements may be used without departing from the spirit of the invention.

(25) It will be apparent to those skilled in the art that various modification and variations can be made in the embodiments of the present invention without departing from the spirit or scope of the invention. Thus, it is intended that the present invention cover modifications and variations that come within the scope of the appended claims and their equivalents.