Patent Description:
In the related art, a non-clogging pump provided with an impeller is known. Such a non-clogging pump is disclosed in Japanese Unexamined Patent Publication No. <CIT>, <CIT>, and <CIT>. Furthermore, <CIT> discloses a non-clogging pump at least not having the features of the characterizing portion of claim <NUM>. Further prior art is shown in <CIT> and <CIT>.

Japanese Unexamined Patent Publication No.<CIT>discloses a vertical type non-clogging pump that includes an impeller and a flow straightener disposed immediately below the impeller and outside a suction port. The flow straightener includes a flow straightening plate that guides and pushes fibrous foreign matter having a cloth shape, a strip shape, or the like toward the outer periphery side of the impeller. The flow straightening plate is formed so as to spread in a tapered shape and radially from the lower side toward the upper side. The flow straightener is configured to pass the foreign matter by guiding and pushing the foreign matter toward the outer periphery side of the impeller by the flow straightening plate.

However, in the non-clogging pump disclosed in <CIT>, since the flow straightener is disposed immediately below the impeller, there is a case where the foreign matter is caught between the flow straightener and the impeller, and therefore, there is a problem in that the passage performance of the foreign matter is poor. Further, in the non-clogging pump disclosed in <CIT>, since the flow straightener is provided as a dedicated configuration for passing the foreign matter on the suction port side of the impeller, there is also a problem in that a device configuration is complicated.

The present invention has been made in order to solve the problems as described above, and an object of the present invention is to provide a non-clogging pump in which it is possible to improve the passage performance of foreign matter without complicating a device configuration. Solution to Problem.

In order to achieve the above object, the present invention is defined by a non-clogging pump according to claim <NUM>. According to a first aspect of the present invention, there is provided a non-clogging pump including: a pump casing provided with a suction port; and an impeller that includes a main plate portion and two or more vane portions that are disposed on a suction port side of the main plate portion, is fixed to one end of a rotating shaft, and is disposed inside the pump casing, in which the main plate portion includes a main plate protrusion portion that protrudes in a counter-inflow direction that is a direction opposite to an inflow direction of water from the suction port, which substantially coincides with an axial direction of the rotating shaft, toward an inner periphery side in a radial direction of the rotating shaft, the vane portion includes a first end face that is an end face in the counter-inflow direction, which is located on an outer periphery side in the radial direction, and extends in a direction intersecting the counter-inflow direction, and a second end face that is an end face in the counter-inflow direction, which is connected to the first end face from the inner periphery side in the radial direction of the first end face and located on the inner periphery side in the radial direction, and is inclined with respect to the first end face so as to be located on a counter-inflow direction side toward the inner periphery side in the radial direction, and is connected to the main plate protrusion portion at an inner periphery-side end portion, and an inner peripheral wall that forms the suction port of the pump casing includes a suction port protrusion portion that is provided at a portion in a rotation direction of the rotating shaft, is disposed along the second end face with a gap from the second end face, and protrudes toward a center side of the suction port.

In the non-clogging pump according to the above aspect of the present invention, as described above, the vane portion is configured to include the first end face that is an end face in the counter-inflow direction, which is located on the outer periphery side in the radial direction of the rotating shaft, and extends in the direction intersecting the counter-inflow direction, and the second end face (a leading edge) that is an end face in the counter-inflow direction, which is connected to the first end face from the inner periphery side in the radial direction of the first end face and located on the inner periphery side in the radial direction, and is inclined with respect to the first end face so as to be located on the counter-inflow direction side toward the inner periphery side in the radial direction. In this way, it is possible to guide foreign matter sucked from the suction port to the outer periphery side of the impeller along the second end face and the first end face without providing a flow straightener having a configuration different from that of the impeller, as in the related art, and therefore, it is possible to restrain the foreign matter from being caught in the pump chamber due to the foreign matter being entangled in the impeller with the rotation of the impeller. That is, it is possible to guide the foreign matter to the outer periphery side of the impeller such that the foreign matter passes by the impeller itself without providing a flow straightener that is a dedicated configuration in which the foreign matter is easily caught, as in the related art. Further, since it is not necessary to provide a flow straightener as in the related art, the gap between a flow straightener and a pump main body (an impeller) is not clogged with soft foreign matter, and thus it is possible to improve the passage performance of the foreign matter. As a result, it is possible to improve the passage performance of the foreign matter without complicating a device configuration. Further, due to providing two or more vane portions, it is possible to dispose the two or more vane portions in a well-balanced manner around the rotating shaft, and therefore, compared to a case where only one vane portion is provided, it is possible to reduce vibration associated with the rotation of the impeller. Therefore, it is possible to suppress a decrease in pump efficiency.

Further, the main plate portion is provided with the main plate protrusion portion that protrudes in the counter-inflow direction toward the inner periphery side in the radial direction of the rotating shaft, and the suction port protrusion portion that protrudes to the center side of suction port is provided on the inner peripheral wall that forms the suction port of the pump casing. Due to the suction port protrusion portion, the center of the swirling flow (the spirally swirling flow that is generated by the rotation of the impeller) that is generated in the vicinity of the suction port can be made to be eccentric when viewed from the axial direction of the rotating shaft, and therefore, the center of the swirling flow can be shifted from the main plate protrusion portion. Further, the foreign matter can be sucked in at an angle with respect to the direction of the rotating shaft. With the above, it is possible to restrain the foreign matter from being entangled in the main plate protrusion portion. Further, the opening area of the suction port is reduced due to the suction port protrusion portion, so that it is possible to increase the suction speed of water and the foreign matter. Therefore, it is possible to suppress a decrease in suction flow velocity even in a small water volume range. Further, since it is possible to suck the foreign matter at an angle with respect to the axial direction of the rotating shaft (the inflow direction) due to the second end face (since a configuration can be made such that the foreign matter is not sucked straight with respect to the inflow direction), it is possible to allow the foreign matter to effectively flow toward the discharge port.

In the non-clogging pump according to the above aspect, preferably, an angle formed by the second end face and the first end face is an obtuse angle. With this configuration, it is possible to cause the second end face to protrude toward the suction port side with respect to the first end face, and therefore, by the second end face, it is possible to crush and cut the foreign matter (rubber gloves, stockings, or the like in a state of being caught in a tip clearance (the gap between the first end face of the vane portion and the surface of the pump casing facing the first end face)) that stays across the suction port due to being caught in the end face of the vane portion. In this way, it is possible to prevent the foreign matter from being constrained by the tip clearance across the suction port.

In the non-clogging pump according to the above aspect, preferably, the suction port protrusion portion is formed in an angular range of <NUM> degrees or larger around the rotating shaft when viewed from the axial direction of the rotating shaft. With this configuration, the suction port protrusion portion can be provided in a relatively large angular range, and therefore, the center of the swirling flow that is generated in the vicinity of the suction port can be reliably made to be eccentric. As a result, it is possible to effectively restrain the foreign matter from being entangled in the main plate protrusion portion. Further, since it is possible to cause the suction port protrusion portion to protrude from a relatively large angular range, the opening area of the suction port can be reduced due to the suction port protrusion portion, and thus it is possible to further increase the suction speed of water and the foreign matter. Therefore, it is possible to further suppress a decrease in suction flow velocity even in a small water volume range. Further, since the suction port protrusion portion is formed in a relatively wide angular range, it is possible to restrain soft foreign matter from being entangled in and constrained by the suction port protrusion portion.

In the non-clogging pump according to the above aspect, preferably, an inner periphery-side end portion of the suction port protrusion portion is disposed on an inner periphery side in the radial direction of the rotating shaft with respect to the inner periphery-side end portion of the vane portion that is connected to the main plate protrusion portion, or at a position substantially corresponding to the inner periphery-side end portion of the vane portion in the radial direction. With this configuration, it is possible to cause the suction port protrusion portion to protrude to the vicinity of the main plate protrusion portion, and therefore, when the vane portion passes near the suction port protrusion portion, the foreign matter can be reliably removed by the suction port protrusion portion. As a result, it is possible to restrain the foreign matter from being stacked on the second end face. Further, the foreign matter can be cut and crushed to a size in which the foreign matter is not caught in the tongue portion, the outer periphery of the vane portion, and a tip clearance.

According to a second aspect of the present invention and in combination with at least the first aspect of the invention, the main plate protrusion portion has, at a tip thereof, an inclined surface inclined with respect to a direction orthogonal to the counter-inflow direction, the inclined surface being configured such that when the impeller rotates, the inclined surface rotates and a force that pushes the foreign matter to the top portion of the inclined surface along the inclined surface can be applied to the foreign matter. As a result, the force acting on the foreign matter in the inflow direction can be made non-uniform, and therefore, in a case where the foreign matter is entangled in the inclined surface, the foreign matter is out of balance and can be removed from the inclined surface. Further, even in a case where soft foreign matter is twisted, the center of the twist deviating from the rotation center axis of the rotating shaft and coming near to the top portion due to rotation and the foreign matter receiving a force that pushes it to the top portion along the inclined surface are combined, so that it becomes easy to remove the foreign matter from the suction-side end face of the impeller.

Preferably, the tip of the main plate protrusion portion has a substantially circular shape when viewed from the axial direction of the rotating shaft. With this configuration, the top portion of the inclined surface is formed to be round, and therefore, the effect of removing the foreign matter from the inclined surface is enhanced.

Preferably, the inclined surface is provided on an entire tip of the main plate protrusion portion. With this configuration, when the inclined surface rotates, a larger force that pushes the foreign matter to the top portion of the inclined surface along the inclined surface can be applied to the foreign matter. Therefore, in a case where the foreign matter is entangled in the inclined surface, the balance of the foreign matter can be more greatly disturbed, and therefore, it is possible to effectively remove the foreign matter from the inclined surface.

Preferably, an apex on the counter-inflow direction side of the inclined surface is disposed at a substantially intermediate position between the two vane portions that are located in the vicinity of the apex in the rotation direction of the rotating shaft. With this configuration, both the distance between the top portion and the vane portion on one side and the distance between the top portion and the vane portion on the other side can be reduced (substantially minimized), and therefore, after the foreign matter is removed from the inclined surface, it can be quickly crushed by the vane portion and the suction port protrusion portion and pushed into the suction port. As a result, the passage performance of the foreign matter can be further improved.

Preferably, the inner periphery-side end portion in the counter-inflow direction of the suction port protrusion portion is disposed close to a side surface of the main plate protrusion portion when viewed from the axial direction of the rotating shaft. With this configuration, the main plate protrusion portion and the suction port protrusion portion can be disposed with a narrow (small) gap, and therefore, the foreign matter can be effectively cut and crushed in the gap between the main plate protrusion portion and the suction port protrusion portion, and the foreign matter can be more effectively removed from the inclined surface of the impeller.

Preferably, the inner periphery-side end portion in the counter-inflow direction of the suction port protrusion portion is disposed between an apex on the counter-inflow direction side of the inclined surface and a point that is located on a bottom on an opposite direction side to the counter-inflow direction of the inclined surface, in the axial direction of the rotating shaft. With this configuration, the side surface of the formed inclined surface has a non-uniform length in the direction of the rotating shaft, and therefore, the inner periphery-side end portion of the suction port protrusion portion and the side surface of the main plate protrusion portion smoothly repeat "approach" and "separation" with the rotation of the impeller, so that the foreign matter is easily removed from the inclined surface of the impeller. As a result, the passage performance of the foreign matter can be further improved.

In the non-clogging pump according to the above aspects, preferably, an inner periphery-side portion in the radial direction of the vane portion (of the rotating shaft) is inclined to be located so as to spread to the outer periphery side in the radial direction toward the counter-inflow direction. With this configuration, the vane portion is formed in a so-called screw shape. Therefore, a force that pushes the foreign matter into the impeller can act on the foreign matter with the rotation of the impeller, and therefore, the foreign matter is easily removed from the gap between the suction port protrusion portion and the vane portion. As a result, the passage performance of the foreign matter can be further improved.

In the non-clogging pump according to the above aspects, preferably, the pump casing has a foreign matter discharge groove that has an elongated shape, is provided on a facing surface on the counter-inflow direction side of the impeller, which faces the impeller, and extends from the inner periphery side toward the outer periphery side in the radial direction of the rotating shaft, and an end portion on the inner periphery side in the radial direction of the foreign matter discharge groove extends to the suction port protrusion portion. With this configuration, due to the foreign matter discharge groove, the constraint of the foreign matter in the gap between the first end face and the second end face of the vane portion (the impeller) and the facing surface of the pump casing, which faces the first end face and the second end face of the vane portion can be suppressed. As a result, the passage performance of the foreign matter can be further improved.

In this case, preferably, the pump casing includes the facing surface that surrounds the suction port, faces the impeller from the suction port side, and extends in a direction substantially orthogonal to the axial direction of the rotating shaft, the foreign matter discharge groove is provided on the facing surface, and the foreign matter discharge groove is provided with an edge portion, which changes an angle at which the foreign matter discharge groove extends, in the vicinity of a boundary portion between the suction port protrusion portion and the facing surface when viewed from the axial direction of the rotating shaft. With this configuration, the foreign matter is caught in the edge portion, and the vane portion of the impeller passes over the foreign matter caught in the edge portion, so that the foreign matter can be cut.

In the configuration in which the pump casing has the foreign matter discharge groove, preferably, an end portion on the outer periphery side in the radial direction of the foreign matter discharge groove is located on the outer periphery side with respect to the vane portion in the radial direction. With this configuration, due to the foreign matter discharge groove, the foreign matter can be led to the outside of the gap between the first end face of the vane portion (the impeller) and the facing surface of the pump casing, which faces the first end face of the vane portion, and therefore, the passage performance of the foreign matter can be further improved.

In the configuration in which the pump casing has the foreign matter discharge groove, preferably, the foreign matter discharge groove is configured to become deeper toward a downstream side from an upstream side in the rotation direction of the impeller along the rotation direction of the impeller. With this configuration, the foreign matter can be effectively pushed into the foreign matter discharge groove along the rotation direction of the impeller, and therefore, the passage performance of the foreign matter can be further improved.

In the configuration in which the pump casing has the foreign matter discharge groove, preferably, the foreign matter discharge groove is configured to widen in width toward an outer periphery from a center of the pump casing. With this configuration, the foreign matter discharge groove is gradually widened in the discharge direction, and therefore, the effect of pushing out the foreign matter in the discharge direction can be obtained.

In the non-clogging pump according to the above aspects, preferably, in the rotation direction of the rotating shaft, an upstream-side side surface of the suction port protrusion portion is disposed in an angular range between a tongue portion of the pump casing and an angular position on an upstream side by <NUM> degrees with respect to the tongue portion. With this configuration, the upstream-side side surface, which is located at a position where the foreign matter is easily pushed into the pump chamber, can be disposed at a position relatively close to the tongue portion. As a result, the sucked foreign matter can be immediately discharged with a time when it is present in the pump chamber (volute) shortened. Therefore, it is possible to make it difficult for the foreign matter to be entangled in the tongue portion, the impeller, or the like. As a result, the passage performance of the foreign matter can be further improved.

In the non-clogging pump according to the above aspects, preferably, the impeller is configured such that a flow path on a negative pressure surface side of the vane portion is narrower than a flow path on a pressure surface side of the vane portion on the main plate portion side and the inner periphery side in the radial direction. With this configuration, by narrowing the flow path on the negative pressure surface side, the stay of the sucked foreign matter in the flow path on the negative pressure surface side is suppressed, and the foreign matter can be pushed into (be brought near) the flow path on the pressure surface side. That is, it is possible to easily discharge the foreign matter. As a result, the passage performance of the foreign matter can be further improved.

In the non-clogging pump according to the above aspects, preferably, the main plate portion is provided with a weight portion having an annular shape and applying an inertial force to the impeller. With this configuration, due to a flywheel effect that is obtained by the weight portion, the inertial force of the rotating impeller can be increased, and therefore, an increase in torque due to the crushing of the foreign matter and an impact can be canceled out. The flywheel effect is an effect of making the rotation speed of a rotating body rotating around a predetermined axis as uniform as possible (an effect of eliminating unevenness of the rotation speed of the rotating body).

In the non-clogging pump according to the above aspects, preferably, a thickness on the outer periphery side in the radial direction of the vane portion is larger than a thickness on the inner periphery side in the radial direction of the vane portion. With this configuration, due to the flywheel effect that is obtained by the vane portion, the inertial force of the rotating impeller can be increased, and therefore, an increase in torque due to the crushing of the foreign matter and an impact can be canceled out. Further, it is possible to obtain the flywheel effect by the vane portion that is an existing configuration.

In the non-clogging pump according to the above aspects, preferably, the non-clogging pump further includes an electric motor that rotates the rotating shaft, in which the non-clogging pump is configured such that a rotational frequency of the electric motor is changeable, and is configured such that in a case where a drive power value of the electric motor falls below a predetermined first threshold value, the rotational frequency of the electric motor is increased until the drive power value of the electric motor reaches the predetermined first threshold value or a predetermined second threshold value exceeding the predetermined first threshold value. With this configuration, the span for crushing the foreign matter can be shortened by increasing the rotational frequency of the electric motor, and therefore, the foreign matter can be crushed finely. Further, by applying a larger centrifugal force to the passing foreign matter, it is possible to improve the action of pushing up the foreign matter on the inclined surface, and therefore, the foreign matter can be easily removed from the inclined surface of the impeller. Further, a water suction speed (suction water amount) can be increased. As a result, the passage performance of the foreign matter can be further improved.

Preferably, the non-clogging pump further includes an electric motor that rotates the rotating shaft, in which the non-clogging pump is configured such that in a case where a state where a drive power value of the electric motor exceeds a drive power reference value is continued for a predetermined time or longer, the impeller is rotated in a reverse direction when it is repeatedly determined that the state where the drive power value of the electric motor exceeds the drive power reference value is continued for a predetermined time or longer, even if restart is attempted with the electric motor stopped by a predetermined number of times. With this configuration, due to the reverse rotation of the impeller, the side surface of the main plate protrusion portion and the inner periphery-side end portion of the suction port protrusion portion repeat approach and separation with respect to the foreign matter returned to the inner periphery side of the impeller, and therefore, the non-clogging pump can effectively remove the foreign matter entangled in the impeller, the foreign matter constrained in the pump chamber, or the like.

In the non-clogging pump according to the above aspects, preferably, the inner peripheral wall that forms the suction port of the pump casing further includes, in addition to the suction port protrusion portion, a recessed portion that is provided on a side opposite to a side where the suction port protrusion portion is disposed with respect to the rotating shaft when viewed in a plan view, and is recessed to an outer periphery side in the radial direction of the suction port. With this configuration, by providing the suction port protrusion portion and the recessed portion, the center of the swirling flow that is generated in the vicinity of the suction port can be made to be more eccentric compared to a case where only the suction port protrusion portion is provided. Therefore, it is possible to further suppress the entanglement of the foreign matter in the main plate protrusion portion. As a result, the passage performance of the foreign matter can be further improved. Further, due to the recessed portion, even if large foreign matter flows in, the foreign matter is moved to the recessed portion, and the foreign matter can be crushed to a size that allows passage, by "cutting action and crushing action" due to a change in the relative position between the downstream-side side wall in the rotation direction of the recessed portion (the rotation direction of the impeller) and the pressure surface-side edge of the leading edge (the second end face) of the rotating vane portion.

According to the present invention, as described above, it is possible to improve the passage performance of the foreign matter without complicating a device configuration.

Hereinafter, an embodiment will be described based on the drawings.

A non-clogging pump <NUM> of an embodiment will be described with reference to <FIG>. The non-clogging pump <NUM> is a vertical type submersible electric pump in which a rotating shaft <NUM> extends in an up-down direction (a Z direction).

As shown in <FIG>, the non-clogging pump <NUM> includes the rotating shaft <NUM>, an electric motor <NUM>, a pump casing <NUM>, and an impeller <NUM>.

Here, the non-clogging pump <NUM> of the present embodiment is configured to allow even relatively long and wide soft foreign matter (contaminant) (soft foreign matter) or the like, such as a towel, stockings, rubber gloves, bandages, or diapers, to pass (be sucked from a suction port <NUM> of the pump casing <NUM> and discharged from a discharge port <NUM> of the pump casing <NUM>) without clogging.

Further, the non-clogging pump <NUM> is usually used such that the flow velocity in a discharge pipe (not shown) that is disposed on the downstream side of the discharge port <NUM> is equal to or higher than the flow velocity (for example, <NUM>/s) at which it is difficult for a sediment to accumulate in the discharge pipe, and is equal or lower than the flow velocity (for example, <NUM>/s) at which a pipe wall or painting in the discharge pipe is not damaged. As an example, the non-clogging pump <NUM> is used such that the flow velocity in the discharge pipe is about <NUM>/s.

The rotating shaft <NUM> has a columnar shape extending in the up-down direction. The impeller <NUM> is fixed to one end 1a (a lower end) of the rotating shaft <NUM>, and the electric motor <NUM> (a rotor <NUM>) is fixed to the other end 1b (upper end) side.

Here, in each drawing, an axial direction of the rotating shaft <NUM> is indicated by the Z direction. In the Z directions, the direction (upward direction) from one end 1a toward the other end 1b is indicated by a Z1 direction, and the direction (upward direction) from the other end 1b toward one end 1a is indicated by a Z2 direction.

An inflow direction in the suction port <NUM> of the pump casing <NUM> is a direction that (substantially) coincides with the axial direction of the rotating shaft <NUM> (the Z1 direction from one end 1a toward the other end 1b). Further, a counter-inflow direction, which is the direction opposite to the inflow direction in the suction port <NUM> of the pump casing <NUM>, is also a direction that (substantially) coincides with the axial direction of the rotating shaft <NUM> (the Z2 direction from the other end 1b toward one end 1a).

Further, in each drawing, a radial direction of the rotating shaft <NUM> is indicated by an R direction. In the R direction, a direction from the inner periphery side toward the outer periphery side is indicated by an R1 direction, and a direction from the outer periphery side toward the inner periphery side is indicated by an R2 direction.

Further, in each drawing, a rotation direction of the impeller <NUM> (the rotating shaft <NUM>) is indicated by a K1 direction, and a reverse rotation direction of the impeller <NUM> is indicated by a K2 direction. The rotation direction of the impeller <NUM> is also the rotation direction of the rotating shaft <NUM>. The rotation direction (the K1 direction) of the impeller <NUM> is a counterclockwise direction when viewed from the lower side (the Z2 direction side). However, in a case where the impeller <NUM> (described later) is rotated in the reverse direction, the rotation direction of the impeller <NUM> is the K2 direction.

The electric motor <NUM> is configured to rotate the rotating shaft <NUM>. Then, the electric motor <NUM> is configured to rotate the impeller <NUM> through the rotating shaft <NUM>. Specifically, the electric motor <NUM> includes a stator <NUM> having a coil and a rotor <NUM> disposed on the inner periphery side of the stator <NUM>. The rotating shaft <NUM> is fixed to the rotor <NUM>. The electric motor <NUM> is configured to rotate the rotating shaft <NUM> together with the rotor <NUM> by generating a magnetic field by the stator <NUM>. As a result, the impeller <NUM> rotates.

The electric motor <NUM> is configured such that a rotational frequency thereof can be changed by changing a drive power value of the electric motor <NUM> by the non-clogging pump <NUM>. The non-clogging pump <NUM> is configured to increase the rotational frequency of the electric motor <NUM> until the drive power value of the electric motor <NUM> reaches a predetermined first threshold value or a predetermined second threshold value exceeding the predetermined first threshold value, in a case where the drive power value of the electric motor <NUM> falls below the predetermined first threshold value. In this way, in a case where the drive power value of the electric motor <NUM> falls below the predetermined first threshold value, so that the flow rate of the non-clogging pump <NUM> is reduced (in the case of a small water volume range), it is possible to increase (return) the flow velocity. The predetermined first threshold value and the predetermined second threshold value can be changed by setting.

Further, the non-clogging pump <NUM> is configured to rotate the impeller <NUM> in the reverse direction in a case where the foreign matter is entangled in the impeller <NUM> or the foreign matter is constrained in a pump chamber 3a. Specifically, the non-clogging pump <NUM> is configured such that in a case where a state where the drive power value of the electric motor <NUM> exceeds the drive power reference value is continued for a predetermined time or longer, the impeller <NUM> is rotated in the reverse direction (the K2 direction) when it is repeatedly determined that the state where the drive power value of the electric motor <NUM> exceeds the drive power reference value is continued for a predetermined time or longer, even if restart is attempted with the electric motor stopped by a predetermined number of times. In this way, the impeller <NUM> having a vane portion <NUM> that spirally spreads rotates in the reverse direction, so that a side surface 72a of a main plate protrusion portion <NUM> (a tubular portion <NUM>) and an inner periphery-side end portion 50c of a suction port protrusion portion <NUM> repeat approach and separation with respect to the foreign matter returned to the inner periphery side of the impeller <NUM>, and therefore, the non-clogging pump <NUM> can effectively remove the foreign matter entangled in the impeller <NUM>, the foreign matter constrained in the pump chamber 3a, or the like. The predetermined time and the predetermined number of times can be changed by setting.

As shown in <FIG>, in the pump casing <NUM>, the impeller <NUM> is disposed in the pump chamber 3a inside thereof. The pump chamber 3a is formed in a volute shape. The pump casing <NUM> is provided with a tongue portion 4a at a corner portion between the space where the impeller <NUM> is disposed and the space on the discharge port <NUM> side. The tongue portion 4a is a portion that protrudes to the inside of the pump casing <NUM> to divide a flow path when viewed from the Z direction (described later).

As shown in <FIG>, the pump casing <NUM> includes a pump casing main body <NUM> and a suction cover <NUM> that is detachably installed to the pump casing main body <NUM> from below. The pump casing main body <NUM> is provided with the discharge port <NUM> that is located at the most downstream of the pump casing <NUM>. The suction cover <NUM> is provided with the suction port <NUM> that is located at the most upstream of the pump casing <NUM>.

The impeller <NUM> is a so-called semi-open type impeller. The impeller <NUM> is disposed inside the pump casing <NUM>. The impeller <NUM> includes a main plate portion <NUM> (a shroud) and two vane portions <NUM> (vanes) that are disposed on the suction port <NUM> side (the lower side) of the main plate portion <NUM>.

The two vane portions <NUM> are disposed evenly when viewed from the Z direction so as to be rotationally symmetric with respect to a rotation center axis α of the rotating shaft <NUM>. That is, the impeller <NUM> is configured such that in a case where the vane portion <NUM> on one side rotates <NUM> degrees around the rotation center axis α of the rotating shaft <NUM>, the vane portion <NUM> on one side overlaps the vane portion <NUM> on the other side. Therefore, the impeller <NUM> is configured such that a fluid reaction force acts on the vane portion <NUM> on one side and the vane portion <NUM> on the other side in a well-balanced manner during rotation. That is, the impeller <NUM> is configured to be able to rotate stably.

As shown in <FIG>, the main plate portion <NUM> includes the main plate protrusion portion <NUM> that protrudes in the counter-inflow direction (the Z2 direction) toward the inner periphery side that is the center side of the main plate portion <NUM> (the rotation center axis α side of the rotating shaft <NUM>).

Specifically, as shown in <FIG>, the main plate portion <NUM> (the main plate protrusion portion <NUM>) is formed in a mountain shape whose center side protrudes downward. The main plate portion <NUM> has the main plate protrusion portion <NUM> provided only at the inner periphery-side portion. The upper-side portion of the main plate portion <NUM> is formed in a flat plate shape extending in a substantially horizontal direction. The lowermost portion (the end portion in the counter-inflow direction) of the main plate portion <NUM> is located in the counter-inflow direction (the downward direction) (the Z2 direction) with respect to the suction port <NUM>. That is, the main plate protrusion portion <NUM> (the impeller <NUM>) protrudes to the outside of the pump casing <NUM> through the suction port <NUM>.

The vane portion <NUM> is connected to the main plate protrusion portion <NUM> at an inner periphery-side end portion <NUM>. The vane portion <NUM> includes a first end face <NUM> and a second end face <NUM> (a leading edge) connected to the first end face <NUM> from the inner periphery side in the radial direction (the R direction) of the first end face <NUM>.

Referring to <FIG> again, the first end face <NUM> is an end face in the counter-inflow direction (the Z2 direction). The first end face <NUM> is located on the outer periphery side in the radial direction (the R direction). The first end face <NUM> extends in a direction intersecting the counter-inflow direction. As an example, the first end face <NUM> extends in a substantially horizontal direction. That is, the first end face <NUM> is a surface substantially orthogonal to the axial direction of the rotating shaft <NUM> (the Z direction). Further, the first end face <NUM> is disposed close to a facing surface 5b (an upper surface) of the suction cover <NUM> (described later), and extends along the facing surface 5b of the suction cover <NUM>.

The second end face <NUM> is an end face in the counter-inflow direction (the Z2 direction). The second end face <NUM> is located on the inner periphery side in the radial direction (the R direction). The second end face <NUM> is connected to the main plate protrusion portion <NUM> at the innermost periphery-side portion thereof. The second end face <NUM> is inclined with respect to the first end face <NUM> so as to be located in the counter-inflow direction (the downward direction) (the Z2 direction) toward the inner periphery side in the radial direction.

As an example, the inclination angle of the second end face <NUM> (the leading edge) is about <NUM> degrees with respect to the horizontal plane. That is, the vane portion <NUM> is formed such that the inner periphery side (the center side) in the radial direction (the R direction) protrudes downward, similarly to the main plate protrusion portion <NUM>.

Referring to <FIG> in which the impeller <NUM> and a foreign matter discharge groove <NUM> (described later) are projected along the rotation direction, as described above, since the first end face <NUM> extends in a substantially horizontal direction and the second end face <NUM> is inclined with respect to the first end face <NUM> so as to be located in the counter-inflow direction (the downward direction) (the Z2 direction) toward the inner periphery side in the radial direction, an angle θ between the first end face <NUM> and the second end face <NUM> is an obtuse angle. As an example, when the inclination angle of the second end face <NUM> (the leading edge) is about <NUM> degrees with respect to the horizontal plane, the angle θ between the first end face <NUM> and the second end face <NUM> is about <NUM> degrees. In <FIG>, a cutting range (cutting location) of the foreign matter by an edge portion 51c of the foreign matter discharge groove <NUM>, which will be described later, is shown by a frame of a one-dot chain line.

As shown in <FIG> and <FIG>, in the vane portion <NUM>, the inner periphery-side portion (the portion on the rotation center axis α side of the rotating shaft <NUM>) is formed in a diagonal flow shape. The diagonal flow shape is a so-called screw shape. Specifically, the inner periphery-side portion of the vane portion <NUM> is inclined to be located so as to spread to the outer periphery side in the radial direction (the R direction) toward the counter-inflow direction.

That is, the inner periphery-side portion of the vane portion <NUM> does not extend straight (linearly) toward the lower side (the counter-inflow direction) (the Z2 direction). The inner periphery-side portion of the vane portion <NUM> is curved so as to warp to the outer periphery side toward the counter-inflow direction. In this manner, in the non-clogging pump <NUM>, the vane portion <NUM> is formed in a diagonal flow shape, so that a mechanical and fluid force that is directed in the inflow direction (upward direction) (the Z1 direction) is applied to the foreign matter sucked from the suction port <NUM> in association with the rotation of the impeller <NUM>, and thus the foreign matter can be effectively pushed to the downstream side.

As shown in <FIG> and <FIG>, the impeller <NUM> is configured such that on the main plate portion <NUM> side and the inner periphery side (the rotation center axis α side of the rotating shaft <NUM>), a flow path S1 (refer to <FIG>) on the negative pressure surface 83a side of the vane portion <NUM> is narrower than a flow path S2 (refer to <FIG>) on the pressure surface 83b side of the vane portion <NUM>.

Specifically, an R-shape portion <NUM> (a curved portion) is provided on the main plate portion <NUM> side and the inner periphery side (the rotation center axis α side of the rotating shaft <NUM>) of the impeller <NUM>. The R-shape portion <NUM> is configured to smoothly connect the main plate protrusion portion <NUM> and the negative pressure surface 83a and the pressure surface 83b connected to the main plate protrusion portion <NUM> when viewed from below. The R-shape portion <NUM> is provided only in the vicinity of the main plate protrusion portion <NUM> when viewed from below.

In the R-shape portion <NUM>, the portion on the negative pressure surface 83a side is formed to have a larger curvature than the portion on the pressure surface 83b side. That is, the R-shape portion <NUM> is formed so as to be located closer to the counter-inflow direction (the downward direction) (the Z2 direction) side such that the narrower flow path S1 is formed on the negative pressure surface 83a side than the pressure surface 83b side.

The impeller <NUM> is provided with two configurations for stably rotating the impeller <NUM> by giving a flywheel effect to the impeller <NUM>. Hereinafter, the configurations will be described in order.

As shown in <FIG> (<FIG>), as a first configuration for giving the flywheel effect, a weight portion <NUM> that applies an inertial force to the impeller <NUM> is provided in the main plate portion <NUM>. The weight portion <NUM> is provided on the upper portion (the portion on the Z1 direction side) of the main plate portion <NUM> and the outer periphery side in the radial direction (the R direction). The weight portion <NUM> is formed in an annular shape surrounding the rotation center axis α of the rotating shaft <NUM>. As an example, the thickness of the weight portion <NUM> is formed to be twice the thickness of the main plate portion <NUM>. The weight portion <NUM> may have a configuration in which it is formed of the same material as the main plate portion <NUM> and provided integrally with the main plate portion <NUM>, or may have separate configuration in which it is formed of a material different from that of the main plate portion <NUM> and installed (fixed) to the main plate portion <NUM>.

As shown in <FIG>, as a second configuration for giving the flywheel effect, the vane portion <NUM> is formed such that the weight of the portion on the outer periphery side in the radial direction (the R direction) is heavier than that of the portion on the inner periphery side in the radial direction (the R direction). Specifically, the vane portion <NUM> is formed such that the thickness on the outer periphery side is larger than the thickness on the inner periphery side. The thickness of the vane portion <NUM> is formed so as to gradually increase toward the outer periphery side from the inner periphery side. In short, the vane portion <NUM> is formed so as to gradually become thicker toward the outer periphery side from the inner periphery side. As an example, the thickness of the vane portion <NUM> on the outer periphery side is formed to be <NUM> times the thickness on the inner periphery side.

The impeller <NUM> can achieve the stabilization of the speed at the time of rotation by the two configurations that give the flywheel effect described above. In this way, the non-clogging pump <NUM> can cancel out an impact and a torque rise which are generated at the time of crushing of the foreign matter, and can suppress an increase in a current value and the occurrence of vibration in the pump operation.

As shown in <FIG> and <FIG>, the main plate protrusion portion <NUM> has a portion made thinner at the lower end thereof. Specifically, in the main plate protrusion portion <NUM>, a tubular portion <NUM> having a cylindrical shape and extending in the Z direction is provided at the end portion thereof in the counter-inflow direction (the downward direction) (the Z2 direction). The tubular portion <NUM> has a smaller diameter than the portion above the tubular portion <NUM>. Therefore, a step is formed between the tubular portion <NUM> and the main plate protrusion portion <NUM> above the tubular portion <NUM>. The tubular portion <NUM> is a portion that is disposed in a height range that overlaps the suction port protrusion portion <NUM> (described later) and is disposed adjacent to the vicinity of the suction port protrusion portion <NUM> (the inner periphery-side end portion 50c). When viewed from the axial direction of the rotating shaft <NUM> (the Z direction) (the downward direction), the outer surface of the tubular portion <NUM> is disposed on the inner periphery side (the rotation center axis α side of the rotating shaft <NUM>) (the R2 direction side) with respect to the inner periphery-side end portion <NUM> of the vane portion <NUM> which is connected to the main plate protrusion portion <NUM>.

The tubular portion <NUM> (the main plate protrusion portion <NUM>) has, at the tip thereof, an inclined surface <NUM> inclined with respect to the direction orthogonal to the counter-inflow direction (the horizontal plane). In short, the tubular portion <NUM> (the main plate protrusion portion <NUM>) generally has a shape such that the tip thereof is diagonally cut so as to have an elliptical cut end. Therefore, the inclined surface <NUM> is not provided at one point (a range corresponding thereto) in the axial direction of the rotating shaft <NUM> (the Z direction), but is provided in a predetermined range in the axial direction of the rotating shaft <NUM> (the Z direction). As an example, the inclination angle of the inclined surface <NUM> with respect to the horizontal plane is smaller than <NUM> degrees. As a more detailed example, the inclination angle of the inclined surface <NUM> with respect to the horizontal plane is <NUM> degrees.

As shown in <FIG>, the tip (the tubular portion <NUM>) of the main plate protrusion portion <NUM> has a substantially circular shape when viewed from the axial direction of the rotating shaft <NUM> (the Z direction) (the downward direction). When viewed from the axial direction of the rotating shaft <NUM> (the Z direction) (the downward direction), the center of the inclined surface <NUM> substantially coincides with the rotation center axis α of the rotating shaft <NUM>. The inclined surface <NUM> is provided on the entire tip of the main plate protrusion portion <NUM>. The entire inclined surface <NUM> is disposed below the suction port <NUM> (excluding the suction port protrusion portion <NUM>) (refer to <FIG>).

An apex 73a (an end point on the lower side) on the counter-inflow direction side of the inclined surface <NUM> is disposed at a substantially intermediate position between the two vane portions <NUM> (a pair of vane portions <NUM>) which are located in the vicinity of the apex 73a in the rotation direction of the rotating shaft <NUM> (the K1 direction). That is, in the rotation direction of the rotating shaft <NUM> (the K1 direction), the two vane portions <NUM> (a pair of vane portions <NUM>) are disposed at angular positions shifted by <NUM> degrees to one side and the other side of the apex 73a.

Here, the non-clogging pump <NUM> is configured to disturb the balance of the foreign matter and facilitate suction by applying a force for pushing the foreign matter toward the apex 73a side along the inclined surface <NUM>.

Further, as shown stepwise in (A) and (B) of <FIG>, the non-clogging pump <NUM> is configured such that in a case where soft foreign matter is entangled in the inclined surface <NUM> outside the pump chamber 3a, the entangled soft foreign matter can be removed by shifting a rotation axis of the soft foreign matter twisted by the inclined surface <NUM> from the rotation center axis α of the rotating shaft <NUM> by a centrifugal force.

As shown in <FIG>, the pump casing <NUM> includes the pump casing main body <NUM> and the suction cover <NUM> provided with the suction port <NUM>, as described above.

Here, the suction port is generally formed in a circular shape when viewed from below. However, the suction port <NUM> of the present embodiment is formed in a shape different from the circular shape. The suction port <NUM> of the present embodiment is formed by an arc and a portion protruding to (located on) the inner periphery side in the radial direction from the arc, when viewed from below.

Specifically, the inner peripheral wall that forms the suction port <NUM> includes the suction port protrusion portion <NUM> provided at a portion thereof in the rotation direction of the rotating shaft <NUM>. The suction port protrusion portion <NUM> is disposed along the second end face <NUM> (the leading edge) of the vane portion <NUM> with a slight gap from the second end face <NUM>. The suction port protrusion portion <NUM> is inclined along the inclined second end face <NUM> of the impeller <NUM> and protrudes toward the inner periphery side (the center side) in the radial direction of the suction port <NUM> (refer to <FIG>). The suction port protrusion portion <NUM> protrudes toward the rotating shaft <NUM> when viewed from below. As an example, in a case where the inclination angle of the second end face <NUM> with respect to the horizontal plane is about <NUM> degrees, the inclination angle of the suction port protrusion portion <NUM> is about <NUM> degrees with respect to the horizontal plane (refer to <FIG> and <FIG>). That is, the inclination angle of the suction port protrusion portion <NUM> is substantially the same as the inclination angle of the second end face <NUM>.

The suction port protrusion portion <NUM> is formed in an angular range θ1 of <NUM> degrees or larger around the rotating shaft <NUM> when viewed from the axial direction of the rotating shaft <NUM> (the Z direction). More specifically, the suction port protrusion portion <NUM> is formed in the angular range θ1 of <NUM> degrees or larger around the rotating shaft <NUM> when viewed from the axial direction of the rotating shaft <NUM> (the Z direction).

The suction port protrusion portion <NUM> has two curved side surfaces (edge portions) that bulge outward when viewed from the Z direction. Hereinafter, the side surface located on the upstream side, out of the two side surfaces of the suction port protrusion portion <NUM>, will be described as an upstream-side side surface 50a, and the side surface located on the downstream side will be described as a downstream-side side surface 50b.

The upstream-side side surface 50a is configured to overlap the rotating vane portion <NUM> prior to the downstream-side side surface 50b when viewed from the Z direction. As an example, the inner periphery-side end portion 50c of the suction port protrusion portion <NUM>, to which the upstream-side side surface 50a and the downstream-side side surface 50b are connected, is formed so as to be an arc of a concentric circle centered on the rotation center axis α.

In the space interposed between the upstream-side side surface 50a and the vane portion <NUM>, a push-in force from the outside toward the inside of the pump chamber 3a is generated due to the rotating vane portion <NUM>. The non-clogging pump <NUM> is configured to suck the foreign matter from between the upstream-side side surface 50a and the rotating vane portion <NUM> by utilizing the push-in force.

As shown in <FIG>, the inner periphery-side end portion 50c of the suction port protrusion portion <NUM> is disposed on the inner periphery side in the radial direction (the R direction) with respect to the inner periphery-side end portion <NUM> of the vane portion <NUM> which is connected to the main plate protrusion portion <NUM> of the impeller <NUM>. That is, the inner periphery-side end portion 50c of the suction port protrusion portion <NUM> is disposed at a position closer to the rotation center axis α of the rotating shaft <NUM> than the inner periphery-side end portion <NUM> of the vane portion <NUM>.

The inner periphery-side end portion 50c (the lower end) in the counter-inflow direction of the suction port protrusion portion <NUM> is disposed between the apex 73a (an end point on the lower side) on the counter-inflow direction side of the inclined surface <NUM> of the impeller <NUM> and a point 73b (an end point of the upper side) that is located at the bottom on the opposite direction side to the counter-inflow direction of the inclined surface <NUM>, in the axial direction of the rotating shaft <NUM> (the Z direction).

The inner periphery-side end portion 50c in the counter-inflow direction of the suction port protrusion portion <NUM> is disposed close to the main plate protrusion portion <NUM> (the tubular portion <NUM>). That is, the inner periphery-side end portion 50c of the suction port protrusion portion <NUM> is disposed with a slight gap between itself and the tubular portion <NUM>. Therefore, the inner periphery-side end portion 50c in the counter-inflow direction of the suction port protrusion portion <NUM> alternately repeats approach (a distance becomes relatively small) and separation (a distance becomes relatively large) with respect to the tubular portion <NUM> having an inclined surface <NUM> when the impeller <NUM> (the tubular portion <NUM> having the inclined surface <NUM>) rotates (refer to <FIG>).

The term "approach" refers to a state where the side surface 72a of the tubular portion <NUM> of the impeller <NUM> and the inner periphery-side end portion 50c of the suction port protrusion portion <NUM> face each other in the horizontal direction at a predetermined rotation position of the impeller <NUM>. The term "separation" refers to a state where the inclined surface <NUM> of the impeller <NUM> and the inner periphery-side end portion 50c of the suction port protrusion portion <NUM> face each other in the horizontal direction at a predetermined rotation position of the impeller <NUM>. In short, the gap between the inner periphery-side end portion 50c of the suction port protrusion portion <NUM> and the impeller <NUM> in the horizontal direction is alternately extended and reduced in association with the rotation of the impeller <NUM>.

At the rotation position in the approach state shown in (A) of <FIG>, the suction port protrusion portion <NUM> is disposed at a position closer to the apex 73a (the end point on the lower side) on the counter-inflow direction side of the inclined surface <NUM> of the impeller <NUM> than the point 73b (the end point on the upper side) located on the bottom on the opposite direction side to the counter-inflow direction of the inclined surface <NUM> in the direction (the horizontal direction) orthogonal to the axial direction of the rotating shaft <NUM> (refer to <FIG>).

On the other hand, at the rotation position in the separation state shown in (B) of <FIG>, the suction port protrusion portion <NUM> is disposed at a position closer to the point 73b than the apex 73a in the direction (the horizontal direction) orthogonal to the axial direction of the rotating shaft <NUM> (refer to <FIG>).

As shown in <FIG>, in the rotation direction of the rotating shaft <NUM>, the upstream-side side surface 50a of the suction port protrusion portion <NUM> is disposed in an angular range θa between the tongue portion 4a of the pump casing <NUM> and the angular position on the upstream side (the upstream side in a flow direction of water in the pump chamber 3a) by <NUM> degrees from the tongue portion 4a.

Therefore, the non-clogging pump <NUM> is configured to be capable of sucking the foreign matter from the vicinity of the upstream-side side surface 50a of the suction port protrusion portion <NUM> disposed at a position relatively close to the tongue portion 4a through the suction port <NUM>. As a result, the non-clogging pump <NUM> can transport the sucked foreign matter to the discharge port <NUM> through a path of a relatively short distance.

In the rotation direction of the rotating shaft <NUM>, the upstream-side side surface 50a of the suction port protrusion portion <NUM> is more preferably disposed in an angular range 8b between the tongue portion 4a of the pump casing <NUM> and the angular position on the upstream side (the upstream side in the flow direction of water in the pump chamber 3a) by <NUM> degrees from the tongue portion 4a. With this configuration, it becomes possible to transport the sucked foreign matter to the discharge port <NUM> through a path of a shorter distance.

As shown in <FIG> (<FIG>), the pump casing <NUM> (the suction cover <NUM>) has the foreign matter discharge groove <NUM>. The foreign matter discharge groove <NUM> is provided on the facing surface 5b (the upper surface) on the counter-inflow direction side (the Z2 direction side) of the impeller <NUM>, which faces the impeller <NUM>. The foreign matter discharge groove <NUM> has an elongated shape extending from the inner periphery side in the radial direction (the R direction) toward the outer periphery side.

As shown in (A) to (D) of <FIG>, the foreign matter discharge groove <NUM> has a shape in which the cross section in the circumferential direction is half of a substantially teardrop shape. The foreign matter discharge groove <NUM> is formed so as to gradually increase in the rotation direction (the K1 direction) of the impeller <NUM> from the inner periphery side in the radial direction toward the outer periphery side. That is, the foreign matter discharge groove <NUM> is formed such that the width of the foreign matter discharge groove <NUM> increases and R of the bottom surface becomes gentle from the inner periphery side in the radial direction toward the outer periphery side.

As shown in <FIG>, the pump casing <NUM> (the suction cover <NUM>) includes the facing surface 5b that surrounds the suction port <NUM>, faces the impeller <NUM> from the suction port <NUM> side, and extends in the direction substantially orthogonal to the axial direction of the rotating shaft <NUM>. The foreign matter discharge groove <NUM> is provided in the facing surface 5b. In the foreign matter discharge groove <NUM>, the edge portion 51c that changes the angle at which the foreign matter discharge groove <NUM> extends is provided in the vicinity of the boundary portion between the suction port protrusion portion <NUM> and the facing surface 5b when viewed from the axial direction of the rotating shaft <NUM>.

The edge portion 51c on the upstream side in the rotation direction of the impeller changes from the upstream side toward the downstream side by an angle of a predetermined angle θ10 with respect to a tangent line to the foreign matter discharge groove <NUM> formed in the suction port protrusion portion <NUM> when viewed from the axial direction of the rotating shaft <NUM>. The edge portion 51c on the downstream side in the rotation direction of the impeller changes from the upstream side toward the downstream side by an angle of a predetermined angle θ11 with respect to a tangent line to the foreign matter discharge groove <NUM> formed in the suction port protrusion portion <NUM> when viewed from the axial direction of the rotating shaft <NUM>. As an example, the predetermined angle θ10 is <NUM> degrees and the predetermined angle θ11 is <NUM> degrees.

As shown in <FIG> (<FIG>), an end portion 51a on the inner periphery side in the radial direction of the foreign matter discharge groove <NUM> extends to the suction port protrusion portion <NUM>. An end portion 51b on the outer periphery side in the radial direction of the foreign matter discharge groove <NUM> is located on the outer periphery side with respect to the vane portion <NUM> in the radial direction (the R direction). That is, the foreign matter discharge groove <NUM> extends to the outer periphery side with respect to the gap (slight gap) between the vane portion <NUM> where a constraint occurs and the facing surface 5b of the suction cover <NUM> in the radial direction (the R direction). The foreign matter discharge groove <NUM> extends from the inner periphery side in the radial direction (the R direction) toward the outer periphery side so as to swirl along the rotation direction (the K1 direction) of the impeller <NUM>.

Specifically, the foreign matter discharge groove <NUM> has a curved shape along the flow direction of a swirling flow that is generated in the pump chamber 3a with the rotation of the rotating shaft <NUM> (a swirling spiral flow that is generated with the rotation of the impeller <NUM>). As an example, in the present embodiment, only one foreign matter discharge groove <NUM> is provided in the pump casing <NUM>. The foreign matter discharge groove <NUM> has a function of restraining the foreign matter from being constrained between the vane portion <NUM> and the pump casing <NUM>. Therefore, the non-clogging pump <NUM> can reliably transport the foreign matter through the discharge port <NUM> by the foreign matter discharge groove <NUM>.

The foreign matter discharge groove <NUM> is configured to gradually become deeper along the rotation direction of the impeller <NUM> toward the downstream side from the upstream side in the rotation direction of the impeller <NUM>.

As shown in <FIG> and <FIG>, the outer portion on the lower side of the suction port <NUM> of the pump casing <NUM> (the suction cover <NUM>) is formed in a smooth shape along the flow of the swirling flow so as not to obstruct the flow of the swirling flow.

Specifically, the suction cover <NUM> is provided with a recessed portion 5a that is recessed from below to above. The recessed portion 5a is disposed in the lower portion of the suction cover <NUM> (on the outer side of the pump chamber 3a). The recessed portion 5a surrounds the suction port <NUM>.

The recessed portion 5a is provided with a plurality of first protrusion portions <NUM> that protrude toward the inner periphery side in the radial direction (the R direction) when viewed from below. The first protrusion portion <NUM> is formed in order to secure an installation location for a member for mounting the suction cover <NUM> to the pump casing main body <NUM>. As an example, the first protrusion portions <NUM> are disposed at equal angular intervals (<NUM> degree intervals) in the circumferential direction of the rotating shaft <NUM>.

In the first protrusion portion <NUM>, the upstream side in the rotation direction is inclined at a relatively small angle θ2 with respect to the outer peripheral surface of the recessed portion 5a when viewed from below. As an example, the first protrusion portion <NUM> is inclined at an angle θ2 of <NUM> degrees or smaller in the rotation direction of the impeller <NUM> with respect to the outer peripheral surface of the recessed portion 5a when viewed from below. As a more specific example, the first protrusion portion <NUM> is inclined at an angle θ2 of <NUM> degrees with respect to the outer peripheral surface of the recessed portion 5a when viewed from below. With such a configuration, a gentle angle is provided with respect to the rotation direction K1, and therefore, it is possible to restrain the foreign matter from getting caught.

Further, the recessed portion 5a is provided with a second protrusion portion <NUM> that extends in the radial direction and protrudes downward, when viewed from below. The second protrusion portion <NUM> is disposed between the outer peripheral surface of the recessed portion 5a and the suction port protrusion portion <NUM> so as to connect the outer peripheral surface of the recessed portion 5a and the suction port protrusion portion <NUM>. The second protrusion portion <NUM> is formed in a rib shape. By forming the second protrusion portion <NUM> in this manner, it is possible to improve the strength of the suction port protrusion portion <NUM>.

In the second protrusion portion <NUM>, the upstream side in the rotation direction is inclined at a relatively small angle θ3 with respect to the bottom surface (the surface on the upper side) of the recessed portion 5a when viewed from below. As an example, the second protrusion portion <NUM> is inclined at an angle θ3 of <NUM> degrees or smaller with respect to the bottom surface of the recessed portion 5a when viewed from below. As a more specific example, the second protrusion portion <NUM> is inclined at an angle θ3 of <NUM> degrees with respect to the bottom surface of the recessed portion 5a when viewed from below. With such a configuration, a gentle angle is provided with respect to the rotation direction K1, and therefore, it is possible to restrain the foreign matter from getting caught.

In the present embodiment, the following effects can be obtained.

In the present embodiment, as described above, the vane portion <NUM> is configured to include the first end face <NUM> that is an end face in the counter-inflow direction (the Z2 direction), which is located on the outer periphery side in the radial direction (the R direction) of the rotating shaft <NUM>, and extends in the direction intersecting the counter-inflow direction, and the second end face <NUM> (the leading edge) that is an end face in the counter-inflow direction, which is connected to the first end face <NUM> from the inner periphery side in the radial direction of the first end face <NUM> and located on the inner periphery side in the radial direction, and is inclined with respect to the first end face <NUM> so as to be located on the counter-inflow direction side toward the inner periphery side in the radial direction. In this way, it is possible to guide the foreign matter sucked from the suction port <NUM> to the outer periphery side of the impeller <NUM> along the second end face <NUM> and the first end face <NUM> without providing a flow straightener having a configuration different from that of the impeller <NUM>, as in the related art, and therefore, it is possible to restrain the pump chamber 3a from being clogged with the foreign matter due to the foreign matter being entangled in the impeller <NUM> with the rotation of the impeller <NUM>. That is, it is possible to guide the foreign matter to the outer periphery side of the impeller <NUM> such that the foreign matter passes by the impeller <NUM> itself without providing a flow straightener that is a dedicated configuration in which the foreign matter is easily caught, as in the related art. Further, since it is not necessary to provide a flow straightener as in the related art, the gap between a flow straightener and a pump main body (an impeller) is not clogged with soft foreign matter, and thus it is possible to improve the passage performance of the foreign matter. As a result, it is possible to improve the passage performance of the foreign matter without complicating a device configuration. Further, due to providing the two or more vane portions <NUM>, it is possible to dispose the two or more vane portions <NUM> in a well-balanced manner around the rotating shaft <NUM>, and therefore, compared to a case where only one vane portion <NUM> is provided, it is possible to reduce vibration associated with the rotation of the impeller <NUM>. Therefore, it is possible to suppress a decrease in pump efficiency.

Further, the main plate portion <NUM> is provided with the main plate protrusion portion <NUM> that protrudes in the counter-inflow direction toward the inner periphery side in the radial direction of the rotating shaft <NUM>, and the suction port protrusion portion <NUM> that protrudes to the center side of suction port <NUM> is provided on the inner peripheral wall that forms the suction port <NUM> of the pump casing <NUM>. Due to the suction port protrusion portion <NUM>, the center of the swirling flow (the spirally swirling flow that is generated by the rotation of the impeller <NUM>) that is generated in the vicinity of the suction port <NUM> can be made to be eccentric when viewed from the axial direction of the rotating shaft <NUM>, and therefore, the center of the swirling flow can be shifted from the main plate protrusion portion <NUM>. Further, the foreign matter can be sucked in at an angle with respect to the direction of the rotating shaft. With the above, it is possible to restrain the foreign matter from being entangled in the main plate protrusion portion <NUM>. Further, the opening area of the suction port <NUM> is reduced due to the suction port protrusion portion <NUM>, so that it is possible to increase the suction speed of water and the foreign matter. Therefore, it is possible to suppress a decrease in suction flow velocity even in a small water volume range. Further, since it is possible to suck the foreign matter at an angle with respect to the axial direction of the rotating shaft <NUM> (the inflow direction) due to the second end face <NUM> (since a configuration can be made such that the foreign matter is not sucked straight with respect to the inflow direction), it is possible to allow the foreign matter to effectively flow toward the discharge port <NUM>.

In the present embodiment, as described above, the angle formed by the second end face <NUM> and the first end face <NUM> is an obtuse angle. In this way, it is possible to cause the second end face <NUM> to protrude toward the suction port <NUM> side with respect to the first end face <NUM>, and therefore, by the second end face <NUM>, it is possible to crush and cut the foreign matter (rubber gloves, stockings, or the like in a state of being caught in a tip clearance (a gap between the first end face <NUM> of the vane portion <NUM> and the surface of the pump casing <NUM> facing the first end face <NUM>)) that stays across the suction port <NUM> due to being caught in the end face of the vane portion <NUM>. In this way, it is possible to prevent the foreign matter from being constrained by the tip clearance across the suction port <NUM>.

In the present embodiment, as described above, the suction port protrusion portion <NUM> is formed in an angular range of <NUM> degrees or larger around the rotating shaft <NUM> when viewed from the axial direction of the rotating shaft <NUM>. In this way, the suction port protrusion portion <NUM> can be provided in a relatively large angular range, and therefore, the center of the swirling flow that is generated in the vicinity of the suction port <NUM> can be reliably made to be eccentric. As a result, it is possible to effectively restrain the foreign matter from being entangled in the main plate protrusion portion <NUM>. Further, since it is possible to cause the suction port protrusion portion <NUM> to protrude from a relatively large angular range, the opening area of the suction port <NUM> can be reduced due to the suction port protrusion portion <NUM>, and thus it is possible to further increase the suction speed of water and the foreign matter. Therefore, it is possible to further suppress a decrease in suction flow velocity even in a small water volume range. Further, since the suction port protrusion portion <NUM> is formed in a relatively wide angular range, it is possible to restrain soft foreign matter from being entangled in and constrained by the suction port protrusion portion <NUM>.

In the present embodiment, as described above, the inner periphery-side end portion 50c of the suction port protrusion portion <NUM> is disposed on an inner periphery side in the radial direction of the rotating shaft <NUM> with respect to the inner periphery-side end portion <NUM> of the vane portion <NUM>, which is connected to the main plate protrusion portion <NUM>, or a position substantially corresponding to the inner periphery-side end portion <NUM> of the vane portion <NUM> in the radial direction. In this way, it is possible to cause the suction port protrusion portion <NUM> to protrude to the vicinity of the main plate protrusion portion <NUM>, and therefore, when the vane portion <NUM> passes near the suction port protrusion portion <NUM>, the foreign matter can be reliably removed by the suction port protrusion portion <NUM>. As a result, it is possible to prevent the foreign matter from being stacked on the second end face <NUM>. Further, the foreign matter can be cut and crushed to a size in which the foreign matter is not caught in the tongue portion 4a, the outer periphery of the vane portion <NUM>, and the tip clearance.

In the present embodiment and according to the second aspect of the invention, as described above, the main plate protrusion portion <NUM> has, at a tip thereof, the inclined surface <NUM> inclined with respect to the direction orthogonal to the counter-inflow direction.

The inclined surface <NUM> is configured such that when the impeller <NUM> rotates, the inclined surface <NUM> rotates and a force that pushes the foreign matter to the top portion of the inclined surface <NUM> along the inclined surface <NUM> can be applied to the foreign matter. As a result, the force acting on the foreign matter in the inflow direction can be made non-uniform, and therefore, in a case where the foreign matter is entangled in the inclined surface <NUM>, the foreign matter is out of balance and can be removed from the inclined surface <NUM>. Further, even in a case where soft foreign matter is twisted, the center of the twist deviating from the rotation center axis of the rotating shaft <NUM> and coming near to the top portion due to rotation and the foreign matter receiving a force that pushes it to the top portion along the inclined surface <NUM> are combined, so that it becomes easy to remove the foreign matter from the suction-side end face of the impeller <NUM>.

In the present embodiment, as described above, the tip of the main plate protrusion portion <NUM> has a substantially circular shape when viewed from the axial direction of the rotating shaft <NUM>. In this way, the top portion of the inclined surface <NUM> is formed to be round, and therefore, the effect of removing the foreign matter from the inclined surface <NUM> is enhanced.

In the present embodiment, as described above, the inclined surface <NUM> is provided on the entire tip of the main plate protrusion portion <NUM>. In this way, when the inclined surface <NUM> rotates, a larger force that pushes the foreign matter to the top portion of the inclined surface <NUM> along the inclined surface <NUM> can be applied to the foreign matter. Therefore, in a case where the foreign matter is entangled in the inclined surface <NUM>, the balance of the foreign matter can be more greatly disturbed, and therefore, it is possible to effectively remove the foreign matter from the inclined surface <NUM>.

In the present embodiment, as described above, the apex 73a on the counter-inflow direction side of the inclined surface <NUM> is disposed at a substantially intermediate position between the two vane portions <NUM> that are located in the vicinity of the apex 73a in the rotation direction of the rotating shaft <NUM>. In this way, both the distance between the top portion and the vane portion <NUM> on one side and the distance between the top portion and the vane portion <NUM> on the other side can be reduced (substantially minimized), and therefore, after the foreign matter is removed from the inclined surface <NUM>, it can be quickly crushed by the vane portion <NUM> and the suction port protrusion portion <NUM> and pushed into the suction port <NUM>. As a result, the passage performance of the foreign matter can be further improved.

In the present embodiment, as described above, the inner periphery-side end portion 50c in the counter-inflow direction of the suction port protrusion portion <NUM> is disposed close to the side surface of the main plate protrusion portion <NUM> when viewed from the axial direction of the rotating shaft <NUM>. In this way, the main plate protrusion portion <NUM> and the suction port protrusion portion <NUM> can be disposed with a narrow (small) gap, and therefore, the foreign matter can be effectively cut and crushed in the gap between the main plate protrusion portion <NUM> and the suction port protrusion portion <NUM>, and the foreign matter can be more effectively removed from the inclined surface <NUM> of the impeller <NUM>.

In the present embodiment, as described above, the inner periphery-side end portion 50c in the counter-inflow direction of the suction port protrusion portion <NUM> is disposed between the apex 73a on the counter-inflow direction side of the inclined surface <NUM> and the point 73b that is located on the bottom on the opposite direction side to the counter-inflow direction of the inclined surface <NUM>, in the axial direction of the rotating shaft <NUM>. With this configuration, the side surface of the formed inclined surface <NUM> has a non-uniform length in the direction of the rotating shaft (the Z direction), and therefore, the inner periphery-side end portion 50c of the suction port protrusion portion <NUM> and the side surface 72a of the main plate protrusion portion <NUM> (the tubular portion <NUM>) smoothly repeat "approach" and "separation" with the rotation of the impeller <NUM>, so that the foreign matter is easily removed from the inclined surface <NUM> of the impeller <NUM>. As a result, the passage performance of the foreign matter can be further improved.

In the present embodiment, as described above, the inner periphery-side portion in the radial direction (of the rotating shaft <NUM>) of the vane portion <NUM> is inclined to be located so as to spread to the outer periphery side in the radial direction toward the counter-inflow direction. In this way, the vane portion <NUM> is formed in a so-called screw shape. Therefore, a force that pushes foreign matter into the impeller <NUM> can act on the foreign matter with the rotation of the impeller <NUM>, and therefore, the foreign matter is easily removed from the gap between the suction port protrusion portion <NUM> and the vane portion <NUM>. As a result, the passage performance of the foreign matter can be further improved.

In the present embodiment, as described above, the pump casing <NUM> has the foreign matter discharge groove <NUM> that has an elongated shape, is provided on the facing surface 5b on the counter-inflow direction side of the impeller <NUM>, which faces the impeller <NUM>, and extends from the inner periphery side toward the outer periphery side in the radial direction of the rotating shaft <NUM>, and the end portion 51a on the inner periphery side in the radial direction of the foreign matter discharge groove <NUM> extends to the suction port protrusion portion <NUM>. In this way, due to the foreign matter discharge groove <NUM>, the constraint of the foreign matter in the gap between the first end face <NUM> and the second end face <NUM> of the vane portion <NUM> (the impeller <NUM>) and the facing surface 5b of the pump casing <NUM>, which faces the first end face <NUM> and the second end face <NUM> of the vane portion <NUM> can be suppressed. As a result, the passage performance of the foreign matter can be further improved.

In the present embodiment, as described above, the pump casing <NUM> includes the facing surface 5b that surrounds the suction port <NUM>, faces the impeller <NUM> from the suction port <NUM> side, and extends in the direction substantially orthogonal to the axial direction of the rotating shaft <NUM>, the foreign matter discharge groove <NUM> is provided on the facing surface 5b, and the foreign matter discharge groove <NUM> is provided with the edge portion 51c, which changes an angle at which the foreign matter discharge groove <NUM> extends, in the vicinity of the boundary portion between the suction port protrusion portion <NUM> and the facing surface 5b when viewed from the axial direction of the rotating shaft <NUM>. In this way, the foreign matter is caught in the edge portion 51c, and the vane portion <NUM> of the impeller <NUM> passes over the foreign matter caught in the edge portion 51c, so that the foreign matter can be cut.

In the present embodiment, as described above, the end portion 51b on the outer periphery side in the radial direction of the foreign matter discharge groove <NUM> is located on the outer periphery side with respect to the vane portion <NUM> in the radial direction. In this way, due to the foreign matter discharge groove <NUM>, the foreign matter can be led to the outside of the gap between the first end face <NUM> of the vane portion <NUM> (the impeller <NUM>) and the facing surface 5b of the pump casing <NUM>, which faces the first end face <NUM> of the vane portion <NUM>, and therefore, the passage performance of the foreign matter can be further improved.

In the present embodiment, as described above, the foreign matter discharge groove <NUM> is configured to become deeper toward the downstream side from the upstream side in the rotation direction of the impeller <NUM> along the rotation direction of the impeller <NUM>. In this way, the foreign matter can be effectively pushed into the foreign matter discharge groove <NUM> along the rotation direction of the impeller <NUM>, and therefore, the passage performance of the foreign matter can be further improved.

In the present embodiment, as described above, the foreign matter discharge groove <NUM> is configured to widen in width toward the outer periphery from the center of the pump casing <NUM>. In this way, the foreign matter discharge groove <NUM> is gradually widened in the discharge direction, and therefore, the effect of pushing out the foreign matter in the discharge direction can be obtained.

In the present embodiment, as described above, in the rotation direction of the rotating shaft <NUM>, the upstream-side side surface 50a of the suction port protrusion portion <NUM> is disposed in the angular range between the tongue portion 4a of the pump casing <NUM> and the angular position on the upstream side by <NUM> degrees with respect to the tongue portion 4a. In this way, the upstream-side side surface 50a, which is located at a position where the foreign matter is easily pushed into the pump chamber, can be disposed at a position relatively close to the tongue portion 4a. As a result, the sucked foreign matter can be immediately discharged with a time when it is present in the pump chamber 3a (volute) shortened. Therefore, it is possible to make it difficult for the foreign matter to be entangled in the tongue portion 4a, the impeller <NUM>, or the like. As a result, the passage performance of the foreign matter can be further improved.

In the present embodiment, as described above, the impeller <NUM> is configured such that the flow path S1 on the negative pressure surface 83a side of the vane portion <NUM> is narrower than the flow path S2 on the pressure surface 83b side of the vane portion <NUM> on the main plate portion <NUM> side and the inner periphery side in the radial direction. In this way, by narrowing the flow path S1 on the negative pressure surface 83a side, the stay of the sucked foreign matter in the flow path S1 on the negative pressure surface 83a side is suppressed, and the foreign matter can be pushed into (be brought near) the flow path S2 on the pressure surface 83b side. That is, it is possible to easily discharge the foreign matter. As a result, the passage performance of the foreign matter can be further improved.

In the present embodiment, as described above, the main plate portion <NUM> is provided with the weight portion <NUM> having an annular shape and applying an inertial force to the impeller <NUM>. In this way, due to a flywheel effect that is obtained by the weight portion <NUM>, the inertial force of the rotating impeller <NUM> can be increased, and therefore, an increase in torque due to the crushing of the foreign matter and an impact can be canceled out. The flywheel effect is an effect of making the rotation speed of a rotating body rotating around a predetermined axis as uniform as possible (an effect of eliminating unevenness of the rotation speed of the rotating body).

In the present embodiment, as described above, the thickness on the outer periphery side in the radial direction of the vane portion <NUM> is larger than the thickness on the inner periphery side in the radial direction of the vane portion <NUM>. In this way, due to the flywheel effect that is obtained by the vane portion <NUM>, the inertial force of the rotating impeller <NUM> can be increased, and therefore, an increase in torque due to the crushing of the foreign matter and an impact can be canceled out. Further, it is possible to obtain the flywheel effect by the vane portion <NUM> that is an existing configuration.

In the present embodiment, as described above, the non-clogging pump further includes the electric motor <NUM> that rotates the rotating shaft <NUM>, and the non-clogging pump is configured such that the rotational frequency of the electric motor <NUM> is changeable, and is configured such that in a case where the drive power value of the electric motor <NUM> falls below a predetermined first threshold value, the rotational frequency of the electric motor <NUM> is increased until the drive power value of the electric motor <NUM> reaches the predetermined first threshold value or the predetermined second threshold value exceeding the predetermined first threshold value. In this way, the span for crushing the foreign matter can be shortened by increasing the rotational frequency of the electric motor <NUM>, and therefore, the foreign matter can be crushed finely. Further, by applying a larger centrifugal force to the passing foreign matter, it is possible to improve the act of pushing up the foreign matter on the inclined surface <NUM>, and therefore, the foreign matter can be easily removed from the inclined surface <NUM> of the impeller <NUM>. Further, a water suction speed (suction water amount) can be increased. As a result, the passage performance of the foreign matter can be further improved.

In the present embodiment, as described above, the non-clogging pump further includes the electric motor <NUM> that rotates the rotating shaft <NUM>, and the non-clogging pump is configured such that in a case where a state where the drive power value of the electric motor <NUM> exceeds the drive power reference value is continued for a predetermined time or longer, the driving of the electric motor <NUM> is stopped, and the impeller <NUM> is rotated in a reverse direction when it is repeatedly determined that the state where the drive power value of the electric motor <NUM> exceeds the drive power reference value is continued for a predetermined time or longer, even if restart is attempted by a predetermined number of times. With this configuration, due to the reverse rotation of the impeller <NUM>, the side surface of the main plate protrusion portion <NUM> and the inner periphery-side end portion 50c of the suction port protrusion portion <NUM> repeat approach and separation with respect to the foreign matter returned to the inner periphery side of the impeller <NUM>, and therefore, the non-clogging pump <NUM> can effectively remove the foreign matter entangled in the impeller <NUM>, the foreign matter constrained in the pump chamber 3a, or the like.

The embodiment disclosed here should be considered to be exemplary and not restrictive in all respects. The scope of the present invention is solely defined by the scope of the claims rather than by the description of the embodiment described above, and further includes all modifications (modification examples) within the scope of the claims.

For example, in the embodiment described above, the example in which only the suction port protrusion portion is provided in the suction port is shown. However, the present invention is not limited to this. In the present invention, the suction port protrusion portion <NUM> and a recessed portion <NUM> may be provided in the suction port <NUM>, as in a non-clogging pump <NUM> of the modification example shown in <FIG>. Specifically, the inner peripheral wall that forms the suction port <NUM> of the pump casing <NUM> further includes, in addition to the suction port protrusion portion <NUM>, the recessed portion <NUM> that is provided on the side opposite to the side where the suction port protrusion portion <NUM> is disposed, with respect to the rotating shaft <NUM> when viewed in a plan view, and recessed to the outer periphery side in the radial direction of the suction port <NUM>. When viewed from the Z1 direction, the recessed portion <NUM> (the area of the portion recessed with respect to the arc of the suction port <NUM>) is formed to be smaller than the suction port protrusion portion <NUM>.

According to the configuration as described above, by providing the suction port protrusion portion <NUM> and the recessed portion <NUM>, the center of the swirling flow that is generated in the vicinity of the suction port <NUM> can be made to be more eccentric, compared to a case where only the suction port protrusion portion <NUM> is provided. Therefore, it is possible to further suppress the entanglement of the foreign matter in the main plate protrusion portion <NUM> (refer to <FIG>). As a result, the passage performance of the foreign matter can be further improved. Further, in a case where relatively large foreign matter flows in, the foreign matter can be cut and crushed by the recessed portion <NUM>. Further, due to the recessed portion <NUM>, even if large foreign matter flows in, the foreign matter is moved to the recessed portion <NUM>, and the foreign matter can be crushed to a size that allows passage, by "cutting action and crushing action" due to a change in the relative position between the downstream-side side wall in the rotation direction of the recessed portion <NUM> (the rotation direction of the impeller <NUM>) and the pressure surface-side edge of the leading edge (the second end face <NUM>) of the rotating vane portion <NUM>.

Further, in the embodiment described above, the example in which the non-clogging pump is a vertical type submersible electric pump is shown. However, the present invention is not limited to this. In the present invention, the non-clogging pump may be a horizontal type submersible electric pump. Further, a vertical type submersible electric pump in which a motor is disposed on the lower side and a pump casing is disposed on the upper side may be adopted.

Further, in the embodiment described above, the example in which the drive source of the non-clogging pump is configured with a motor is shown. However, the present invention is not limited to this. In the present invention, the drive source may be configured with an engine.

Further, in the embodiment described above, the example in which the non-clogging pump that is installed on the ground and operated is adopted is shown. However, the present invention is not limited to this. In the present invention, the pump may be configured as a submersible electric pump in which a float is mounted to the pump to float the pump in water, a motor faces downward, and a suction port faces upward.

Further, in the embodiment described above, the example in which only one foreign matter discharge groove is provided in the pump casing is shown. However, the present invention is not limited to this. In the present invention, a plurality of foreign matter discharge grooves may be provided in the pump casing.

Further, in the embodiment described above, the example is shown in which a configuration is made such that the depth of the foreign matter discharge groove gradually increases toward the downstream side from the upstream side in the rotation direction of the impeller. However, the present invention is not limited to this. In the present invention, a configuration may be made such that the depth of the foreign matter discharge groove gradually decreases toward the downstream side from the upstream side in the rotation direction of the impeller.

Further, in the embodiment described above, the example is shown in which a configuration is made such that the depth of the foreign matter discharge groove gradually increases toward the downstream side from the upstream side in the rotation direction of the impeller. However, the present invention is not limited to this. In the present invention, a configuration may be made such that the depth of the foreign matter discharge groove is changed from the inner periphery side toward the outer periphery side.

Further, in the embodiment described above, the example in which the impeller includes two vane portions is shown. However, the present invention is not limited to this. In the present invention, the impeller may include three or more vane portions.

Further, in the embodiment described above, the example is shown in which in the rotation direction of the rotating shaft, the upstream-side side surface of the suction port protrusion portion is disposed in an angular range between the tongue portion of the pump casing and the angular position on the upstream side by <NUM> degrees (in the K2 direction) with respect to the tongue portion. However, the present invention is not limited to this. In the present invention, for example, in the rotation direction of the rotating shaft, the upstream-side side surface of the suction port protrusion portion may be disposed at an angular position on the upstream side by an angle larger than <NUM> degrees (in the K2 direction) with respect to the tongue portion of the pump casing.

Further, in the embodiment described above, the example is shown in which the first end face is formed so as to extend in a substantially horizontal direction. However, the present invention is not limited to this. In the present invention, the first end face may be formed so as to be inclined with respect to the horizontal direction. For example, the first end face may be inclined with respect to the horizontal direction such that the inner periphery side in the radial direction is located in the counter-inflow direction (the downward direction). In this case, it is preferable that the first end face is inclined at an angle of <NUM> degrees or smaller with respect to the horizontal direction. At this time, the first end face is inclined such that the angle formed by the first end face and the second end face is an obtuse angle.

Further, in the embodiment described above, the example is shown in which the suction port protrusion portion is formed in an angular range of <NUM> degrees or larger around the rotating shaft when viewed from the axial direction of the rotating shaft. However, the present invention is not limited to this. In the present invention, the suction port protrusion portion may be formed in an angular range of less than <NUM> degrees around the rotating shaft when viewed from the axial direction of the rotating shaft.

Further, in the embodiment described above, the example in which the pump casing is composed of two members, that is, the pump casing and the suction cover is shown. However, the present invention is not limited to this. In the present invention, the pump casing may be configured with only one member that is the pump casing main body. In this case, both the suction port and the discharge port are provided in the pump casing main body.

Further, in the embodiment described above, the example is shown in which the tip (the end portion on the lower side) of the main plate protrusion portion has a circular shape when viewed from below. However, the present invention is not limited to this. In the present invention, the tip (the end portion on the lower side) of the main plate protrusion portion may have a shape different from the circular shape, such as a rectangular shape or a gear shape, when viewed from below.

Further, in the embodiment described above, the example is shown in which the second end face (the first end face) of the vane portion is formed so as to be flat when viewed in a side view. However, the present invention is not limited to this. In the present invention, the second end face (the first end face) of the vane portion may be formed so as to be curved when viewed in a side view.

Further, in the embodiment described above, the example is shown in which the inner periphery-side end portion of the suction port protrusion portion is disposed on the inner periphery side in the radial direction of the rotating shaft with respect to the inner periphery-side end portion of the vane portion, which is connected to the main plate protrusion portion. However, the present invention is not limited to this. In the present invention, the inner periphery-side end portion of the suction port protrusion portion may be disposed at a position substantially corresponding to the inner periphery-side end portion of the vane portion in the radial direction.

Claim 1:
A non-clogging pump (<NUM>, <NUM>) for pumping fluid containing foreign matter, the non-clogging pump (<NUM>, <NUM>) comprising:
a pump casing (<NUM>) provided with a suction port (<NUM>); and
an impeller (<NUM>) that includes a main plate portion (<NUM>) and two or more vane portions (<NUM>) that are disposed on a suction port side of the main plate portion (<NUM>), is fixed to one end (1a) of a rotating shaft (<NUM>), and is disposed inside the pump casing (<NUM>),
wherein the main plate portion (<NUM>) includes a main plate protrusion portion (<NUM>) that protrudes in a counter-inflow direction that is a direction opposite to an inflow direction of water from the suction port (<NUM>), which substantially coincides with an axial direction of the rotating shaft (<NUM>), toward an inner periphery side in a radial direction of the rotating shaft (<NUM>),
the vane portion (<NUM>) includes a first end face (<NUM>) that is an end face in the counter-inflow direction, which is located on an outer periphery side in the radial direction, and extends in a direction intersecting the counter-inflow direction, and a second end face (<NUM>) that is an end face in the counter-inflow direction, which is connected to the first end face (<NUM>) from the inner periphery side in the radial direction of the first end face and located on the inner periphery side in the radial direction, and is inclined with respect to the first end face (<NUM>) so as to be located on a counter-inflow direction side toward the inner periphery side in the radial direction, and is connected to the main plate protrusion portion at an inner periphery-side end portion (<NUM>), and
an inner peripheral wall that forms the suction port of the pump casing includes a suction port protrusion portion (<NUM>) that is provided at a portion in a rotation direction of the rotating shaft, is disposed along the second end face with a gap from the second end face, and protrudes toward a center side of the suction port,
characterized in that the main plate protrusion portion (<NUM>) has, at a tip thereof, an inclined surface (<NUM>) inclined with respect to a direction orthogonal to the counter-inflow direction, the inclined surface (<NUM>) being configured such that when the impeller (<NUM>) rotates, the inclined surface rotates and a force that pushes the foreign matter to the top portion of the inclined surface along the inclined surface can be applied to the foreign matter.