KR20240109412A - Apparatus for damping vibration for axial flow pump - Google Patents

Abstract

A vibration damping device for an axial flow pump is provided. A vibration damping device for an axial flow pump according to an embodiment of the present invention is provided in a cylindrical reel shape and includes a suction casing with a through hole on the inside, an inlet guide vane with a shaft on one side and the shaft disposed in the through hole, and suction. It is provided along the outer periphery of the casing, is connected to the shaft, and includes a driving part that drives to adjust the angle of the inlet guide vane.

Description

Vibration damping device for axial flow pump {Apparatus for damping vibration for axial flow pump}

The present invention relates to a vibration damping device for an axial flow pump, and in particular, to a vibration damping device for an axial flow pump that can dampen vibration by minimizing the shroud gap and reducing the relative inflow angle by the shape of the inlet guide vane.

Recently, with the increase in energy costs, interest in improving the efficiency of fluid machines, which consume relatively high energy costs, is increasing. In particular, axial flow pumps have very large suction and discharge flow rates, and various attempts are being made to improve the efficiency of the pump by directing the flow of fluid into and out of the axial direction of the rotor.

However, in the conventional axial flow pump, the inlet guide vane is fixed to the adsorption casing, so performance cannot be adjusted according to changes in flow rate, and the relative flow angle of the rotor changes, causing vibration.

KR 10-2232682 B1

In order to solve the problems of the prior art as described above, an embodiment of the present invention provides a vibration damping device for an axial flow pump that can dampen vibration by minimizing the shroud gap and reducing the relative inflow angle by the shape of the inlet guide vane. We would like to provide

According to one aspect of the present invention for solving the above problem, there is provided a suction casing in a cylindrical reel shape and provided with a through hole on the inside; an inlet guide vane provided with a shaft on one side and the shaft disposed in the through hole; and a driving unit provided along the outer periphery of the suction casing, connected to the shaft, and driven to adjust the angle of the inlet guide vane.

In one embodiment, the shaft may be provided inside the inlet guide vane in a fluid inflow direction.

In one embodiment, the driving unit includes a ring-shaped plate disposed on the outer periphery of the suction casing; a support pin fixed to one surface of the suction casing and rotatably supporting the ring-shaped plate; a bearing provided at an end of the support pin and rotating according to the movement of the plate; a blocking plate covering the through hole with the shaft exposed to the outside; a first coupling portion axially coupled to the shaft to rotate the shaft; a second coupling portion vertically coupled to the plate; and a first link connecting the first coupling portion and the second coupling portion to transmit the rotational force of the plate to the shaft.

In one embodiment, the vibration damping device of the axial flow pump may further include a lever unit coupled to the plate to rotate the plate. Here, the lever part includes a shaft part fixed to one surface of the suction casing; a third coupling part vertically coupled to the plate; An L-shaped lever rotatably coupled to the shaft portion; and a second link connecting the lever and the third coupling unit to transmit the rotational force of the lever to the plate.

In one embodiment, the vibration damping device of the axial flow pump may further include a cylinder that provides power to the driving unit. Here, the cylinder may be connected to the lever.

The vibration damping device for an axial flow pump according to an embodiment of the present invention can attenuate vibration by minimizing the shroud gap and reducing the relative inflow angle by adjusting the shaft position and rotation angle of the inlet guide vane, thereby improving the performance of the axial flow pump. It can be improved.

The vibration damping device for the axial flow pump according to an embodiment of the present invention can reduce the relative inflow angle by adjusting the angle of the inlet guide vane according to the flow rate by adjusting the rotation angle of the inlet guide vane by the driving unit, thereby reducing the relative inflow angle of the axial flow pump. Performance can be further improved.

Figure 1 is a perspective view of a vibration damping device for an axial flow pump according to an embodiment of the present invention.
Figure 2 is a perspective view of the impeller of the vibration damping device for an axial flow pump according to an embodiment of the present invention in a combined state.
Figure 3 is a perspective view of the vibration damping device for an axial flow pump according to an embodiment of the present invention with the cylinder removed.
Figure 4 is a perspective view of an inlet guide vane of a vibration damping device for an axial flow pump according to an embodiment of the present invention.
Figure 5 is a perspective view for explaining the driving part of the vibration damping device for the axial flow pump according to an embodiment of the present invention.
Figure 6 is a perspective view for explaining the lever portion of the vibration damping device for the axial flow pump according to an embodiment of the present invention.

Hereinafter, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention. The present invention may be implemented in many different forms and is not limited to the embodiments described herein. In order to clearly explain the present invention in the drawings, parts not related to the description are omitted, and identical or similar components are given the same reference numerals throughout the specification.

Hereinafter, a vibration damping device for an axial flow pump according to an embodiment of the present invention will be described in more detail with reference to the drawings. Figure 1 is a perspective view of a vibration damping device for an axial flow pump according to an embodiment of the present invention, and Figure 2 is a perspective view of the impeller of the vibration damping device for an axial flow pump according to an embodiment of the present invention in a combined state.

1 and 2, the vibration damping device 100 of an axial flow pump according to an embodiment of the present invention includes a suction casing 110, an inlet guide vane 120, a drive unit 130, and a lever unit 140. and a cylinder 150.

The vibration damping device 100 of the axial flow pump is a device for damping vibration by having a variable inlet guide vane provided in the axial flow pump, and adjusts the angle of the inlet guide vane 120 in the suction casing 110 according to the flow rate. This is a device to improve the performance of the axial flow pump.

The suction casing 110 has the function of suctioning fluid and may be provided at the front of the axial flow pump. The inlet guide vane 120 may be coupled to the inside of the suction casing 110. At this time, the suction casing 110 may be provided with a through hole 112 on the inside. That is, the inlet guide vane 120 may be coupled to the suction casing 110 through the through hole 112. The through holes 112 may be provided as many as the number of inlet guide vanes 120 and may be provided at equal intervals or at equal angles.

This suction casing 110 may be provided in an overall cylindrical reel shape. That is, the suction casing 110 may include a first surface 114, a second surface 116, and an outer peripheral surface 118.

The first surface 114 is a surface coupled to the guide casing at the rear end and may be formed in a plate shape with a certain area. This first surface 114 may be provided in a ring shape. At this time, the outer diameter of the first side 114 may be larger than that of the second side 116.

Here, a first inclined surface 115 may be provided between the first surface 114 and the outer peripheral surface 118. That is, the inside of the suction casing 110 may have a structure in which the inner diameter expands from the inner surface corresponding to the outer peripheral surface 118 toward the first surface 114.

The second surface 116 is a front surface through which fluid flows and is provided opposite the first surface 114 and may be formed in a plate shape with a certain area. This second surface 116 may be provided in a ring shape. At this time, the second surface 116 may have an inner diameter larger than that of the outer peripheral surface 118.

Here, a second inclined surface 117 may be provided between the second surface 116 and the outer peripheral surface 118. That is, the inside of the suction casing 110 may have a structure in which the inner diameter expands from the inner surface corresponding to the outer peripheral surface 118 toward the second surface 116. This second slope 117 may be provided to increase the speed at which fluid flows. In addition, the second inclined surface 117 may form a spare space by adjusting the angle of the inlet guide vane 120. At this time, the angle of the second inclined surface 117 may be determined according to the maximum rotation angle of the inlet guide vane 120 and the shape of the inlet guide vane 120.

The outer peripheral surface 118 may be provided between the first surface 114 and the second surface 116 and have an inner diameter smaller than the inner diameters of the first surface 114 and the second surface 116. A through hole 112 may be formed in this outer peripheral surface 118. Additionally, the outer peripheral surface 118 may be provided with a driving unit 130 as will be described later.

At this time, the outer peripheral surface 118 may be provided with an extension portion 119 at a position corresponding to the through hole 112. The extension portion 119 may be provided to protrude outward from the outer peripheral surface 118. At this time, the extension portion 119 may have a cylindrical tube shape. The extension portion 119 may be provided along the outer peripheral surface 118 as many times as the number of inlet guide vanes 120, and may be equally spaced or equiangular.

The inlet guide vane 120 may be provided inside the suction casing 110. At this time, the inlet guide vane 120 may be coupled to the suction casing 110 through the through hole 112. The inlet guide vanes 120 may be provided in plural numbers to divide the path of the incoming fluid. The inlet guide vane 120 will be described later with reference to FIGS. 3 and 4.

The driving unit 130 may be provided along the outer circumference of the suction casing 110. That is, the driving unit 130 may be provided between the outer peripheral surface 118 and the first and second surfaces 114 and 116 of the suction casing 110. The driving unit 130 is coupled to the inlet guide vane 120 and can be driven to adjust the angle of the inlet guide vane 120. The driving unit 130 will be described later with reference to FIG. 5 .

The lever unit 140 is coupled between the driving unit 130 and the cylinder 150 and can transmit the power of the cylinder 150 to the driving unit 130. At this time, the lever unit 140 may transmit power to rotate the driving unit 130. The lever unit 140 will be described later with reference to FIG. 6 .

The cylinder 150 may provide power to the driving unit 130 through the lever unit 140. For example, cylinder 150 may be a hydraulic cylinder. This cylinder 150 can be driven by being connected to an axial flow pump control system (not shown). That is, when it is determined that the control system of the axial flow pump (not shown) monitors the flow rate and adjusts the angle of the inlet guide vane 120 according to the flow rate, the operation of the cylinder 150 can be controlled.

In this way, the vibration damping device 100 of an axial flow pump according to an embodiment of the present invention can attenuate vibration by minimizing the shroud gap and reducing the relative inflow angle by adjusting the shaft position and rotation angle of the inlet guide vane. Therefore, the performance of the axial flow pump can be improved.

Figure 3 is a perspective view of the cylinder of the vibration damping device for an axial flow pump according to an embodiment of the present invention with the cylinder removed, and Figure 4 is a perspective view of the inlet guide vane of the vibration damping device for an axial flow pump according to an embodiment of the present invention. am.

Referring to FIGS. 3 and 4 , the inlet guide vane 120 may be provided with a shaft 122 on one side. This shaft 122 may be disposed in the through hole 112 of the suction casing 110. That is, the inlet guide vane 120 may be coupled to the suction casing 110 through the shaft 122. Here, the shaft 122 may be a rotation axis for varying the angle of the inlet guide vane 120.

The present applicant confirmed through experiments that the performance characteristics of the axial flow pump change under overload conditions depending on the change in the rotation axis of the inlet guide vane 120 and the shroud gap, and in particular, the relative inflow angle that affects vibration occurs. . In addition, the present applicant examined the change in the relative inflow angle measured at the domain outlet of the inlet guide vane (120) and found that the smaller the increase in the relative inflow angle due to the increase in flow rate in the overflow section, the lower the performance characteristics of the axial flow pump, especially vibration. It was found that it is advantageous in terms of damping characteristics. Based on this fact, the present invention proposes the shape of the inlet guide vane 120 and the position of the shaft 122 to reduce the relative inflow angle.

Here, the shroud spacing of the inlet guide vane 120 may change depending on the formation position of the shaft 122. That is, because the rotation axis of the inlet guide vane 120 changes depending on the position of the shaft 122, the shroud gap may also change. In particular, the shroud gap may be determined according to the maximum rotation range of the inlet guide vane 120. In conclusion, the hydraulic efficiency of the axial flow pump under overload conditions may vary depending on the position of the shaft 122 of the inlet guide vane 120 and the shroud gap.

Therefore, the shaft 122 may be provided on the first side 121 of the inlet guide vane 120 on the shroud side. That is, the shaft 122 may be provided inside the inlet guide vane 120 in the fluid inflow direction. In addition, the shaft 122 may be provided from the first side 121 of the inlet guide vane 120 to the third side 126 on the rotor side.

Here, when the shaft 122 is provided at the center or fourth side 127 of the inlet guide vane 120, the shroud spacing on the trailing edge increases and the relative inflow angle according to the angle change of the inlet guide vane 120 It was confirmed that the decreasing trend was not significant.

At this time, the shaft 122 may be exposed on the outer peripheral surface 118 of the suction casing 110. That is, the shaft 122 may be arranged so that its end is exposed to the outside of the extension portion 119. Accordingly, the shaft 122 may be coupled to the driving unit 130.

A fixing part 125 may be provided between the inlet guide vane 120 and the shaft 122. The fixing part 125 may have a diameter larger than the diameter of the shaft 122. The fixing part 125 may be provided with an outer diameter corresponding to the inner diameter of the extension part 119 of the suction casing 110. At this time, the fixing part 125 may be provided with a groove 124 on the shaft 122 side. This groove 124 may be provided along the outer peripheral surface of the fixing part 125. In addition, the groove portion 124 may be seated on a jaw portion (not shown) provided on the inner surface of the extension portion 119. That is, the fixing part 125 can couple the shaft 122 to the suction casing 110 and rotatably couple it by the groove part 124.

The shape of the first side 121 on the shroud side of the inlet guide vane 120 may be determined according to the maximum rotation angle. For example, the maximum rotation angle of the inlet guide vane 120 may be 25 to 45°. If the maximum rotation angle of the inlet guide vane 120 exceeds 45°, the shroud spacing becomes too large, resulting in a large difference in the relative inflow angle for each position of the inlet guide vane 120. In addition, when the maximum rotation angle of the inlet guide vane 120 is less than 25°, the variable range by adjusting the angle of the inlet guide vane 120 does not sufficiently satisfy the axial flow pump performance under overload conditions.

At this time, the first side 121 may be provided to be curved around the central portion. The first side 121 may have its central portion in contact with the inner surface corresponding to the outer peripheral surface 118 and both ends may be arranged to be spaced apart from the inner surface corresponding to the outer peripheral surface 118 and the second inclined surface 117. Here, the space between the first side 121 and the inner surface corresponding to the outer peripheral surface 118 and the second inclined surface 117 is a space that can be rotated to adjust the angle of the inlet guide vane 120.

The inlet guide vane 120 may have a second side 123 on the hub side in a curved shape. At this time, the second side 123 has a shape corresponding to the external shape of the impeller 10 and may be provided to have a constant curvature so that the distance from the hub is within 1 mm. Here, when the distance from the hub is more than 1 mm, the relative inflow angle increases, and the axial flow pump performance under overload conditions is not sufficiently satisfied.

The inlet guide vane 120 may be formed such that the length of the third side 126 on the shaft 122 side is smaller than the length of the fourth side 127 on the opposite side. That is, because the second side 123 is provided in a shape corresponding to the external shape of the impeller 10, it corresponds to the lower side of the impeller 10 compared to the fourth side 127, which corresponds to the top of the impeller 10. The length of the third side 126 may be small. In addition, the third side 126 may be provided to form an obtuse angle from one end of the second side 123. That is, the third side 126 may be provided between the second side 123 and the first side 121 in a diagonal shape rather than a right angle.

The inlet guide vane 120 may have a fourth side 127 on the opposite side of the shaft 122 in a straight shape. That is, the fourth side 127 may be provided in a straight line from the other end of the second side 123 to the first side 121. The fourth side 127 is disposed in the fluid inflow direction to divide the fluid path.

Figure 5 is a perspective view for explaining the driving part of the vibration damping device for the axial flow pump according to an embodiment of the present invention.

Referring to FIG. 5, the driving unit 130 includes a plate 131, a support pin 132, a bearing 133, a blocking plate 134, a first coupling portion 135, a second coupling portion 136, and a second coupling portion 136. It may include 1 link (137).

The plate 131 may be provided in a ring shape and placed on the outer periphery of the suction casing 110. That is, the plate 131 may be provided to surround the outer circumference of the suction casing 110. At this time, the plate 131 may be provided at a certain distance from the outer peripheral surface 118 of the suction casing 110. In addition, the plate 131 may be provided with a constant width in a direction perpendicular to the outer peripheral surface 118.

One side of the support pin 132 may be fixed to the first surface 114 of the suction casing 110. For example, the support pin 132 may be fixed vertically in the direction from the first surface 114 to the second surface 116. At this time, the support pin 132 can rotatably support the plate 131. A plurality of such support pins 132 may be provided. That is, a plurality of support pins 132 may be arranged at equal intervals or at equal angles along the outer circumference of the ring-shaped plate 131.

The bearing 133 may be provided at the other end of the support pin 132. In addition, the bearing 133 may be rotatably provided. At this time, the bearing 133 is provided with a groove in the center so that the plate 131 can be seated in this groove. The bearing 133 may be coupled to engage with the side surface of the plate 131 in the thickness direction through the groove portion. Therefore, the bearing 133 can rotate according to the movement of the plate 131.

The blocking plate 134 is provided to cover the through hole 112 on the outer peripheral surface 118. At this time, the blocking plate 134 may cover the through hole 112 so that the shaft 122 of the inlet guide vane 120 is exposed to the outside. That is, the blocking plate 134 has a through hole in its center so that it can be inserted into one end of the shaft 122. This blocking plate 134 may be coupled to the cross section of the extension portion 119. At this time, the blocking plate 134 may be provided with a sealing member at the coupling surface with the extension portion 119 and the insertion hole of the shaft 122. For example, the blocking plate 134 may be provided with an O-ring at its coupling surface with the extension portion 119 and at the insertion hole of the shaft 122.

The first coupling portion 135 may be axially coupled to the shaft 122. That is, the central portion of the first coupling portion 135 may be coupled to one end of the shaft 122. For example, the first coupling portion 135 is provided with a through hole in the center, and the shaft 122 can be inserted and fixed into the through hole. That is, the first coupling portion 135 may be arranged in a vertical direction with respect to the shaft 122. As a result, the first coupling portion 135 can adjust the angle of the inlet guide vane 120 by rotating the shaft 122.

The second coupling portion 136 may be vertically coupled to the plate 131. At this time, the second coupling portion 136 may be vertically coupled on the side of the plate 131 facing the second surface 116. The second coupling portion 136 is for transmitting the rotational force of the plate 131 to the first coupling portion 135 through the first link 137.

The first link 137 may connect the first coupling portion 135 and the second coupling portion 136. That is, both ends of the first link 137 may be connected to the first coupling portion 135 and the second coupling portion 136, respectively. At this time, the first link 137 may be arranged in the horizontal direction. As a result, the first link 137 can transmit the rotational force of the plate 131 through the first coupling portion 135 to the shaft 122 through the first coupling portion 135.

In this way, the vibration damping device 100 of the axial flow pump according to an embodiment of the present invention reduces the relative inflow angle by adjusting the angle of the inlet guide vane according to the flow rate by adjusting the rotation angle of the inlet guide vane by the driving unit. Therefore, the performance of the axial flow pump can be further improved.

Figure 6 is a perspective view for explaining the lever portion of the vibration damping device for the axial flow pump according to an embodiment of the present invention.

Referring to FIG. 6, the lever portion 140 may include a shaft portion 142, a third coupling portion 144, a lever 146, and a second link 148.

One side of the shaft portion 142 may be fixed to the first surface 114 of the suction casing 110. For example, the shaft portion 142 may be fixed vertically in the direction from the first surface 114 to the second surface 116. At this time, the shaft portion 142 may be provided so that the other side is disposed between the plate 131 and the second surface 116. That is, the shaft portion 142 may be provided longer than the support pin 132.

The third coupling portion 144 may be vertically coupled to the plate 131. At this time, the third coupling portion 144 may be vertically coupled on the side facing the second surface 116 of the plate 131, similar to the second coupling portion 136. The third coupling portion 144 is for transmitting the rotational force of the lever 146 to the plate 131 through the second link 148.

The lever 146 may be rotatably coupled to the shaft portion 142. That is, the lever 146 may be rotatably coupled to the other end of the shaft portion 142. At this time, the lever 146 may be provided in an L shape. The lever 146 may have a long first part 146a arranged horizontally and a short second part 146b arranged vertically with respect to the shaft portion 142. Here, the first part 146a may be coupled to the cylinder 150.

In addition, the lever 146 can move the first part 146a in the vertical direction and the second part 146b in the horizontal direction by the power supplied from the cylinder 150 with the coupling point with the shaft part 142 as the rotation axis. there is. That is, the lever 146 can convert the vertical movement of the first part 146a into the horizontal movement of the second part 146b.

The second link 148 may connect the lever 146 and the third coupling portion 144. That is, both ends of the second link 148 may be connected to the lever 146 and the third coupling portion 144, respectively. More specifically, one end of the second link 148 may be connected to the end of the second part 146b of the lever 146, and the other end may be connected to the upper end of the third coupling portion 144. At this time, the second link 148 may be arranged in the horizontal direction. As a result, the second link 148 can transmit the rotational force of the lever 146 to the plate 131 through the third coupling portion 144.

The vibration damping device 100 for an axial flow pump according to an embodiment of the present invention configured as described above operates as follows.

First, the power generated from the cylinder 150 is applied to the lever 146 under the control of the axial flow pump control system (not shown). At this time, the first part 146a of the lever 146 may move in the vertical direction according to the power of the cylinder 150. As a result, the second part 146b of the lever 146 can move in the horizontal direction. That is, the lever 146 converts the power provided vertically from the cylinder 150 into horizontal power and transmits it to the plate 131 through the second link 148 and the third coupling portion 144.

The plate 131 moves in the horizontal direction by horizontal power transmitted to the lever 146. At this time, the plate 131 rotates by the bearing 133 due to the horizontal power transmitted to the plate 131. That is, the plate 131 rotates along the outer circumference of the suction casing 110 by the rotatable support of the support pin 132 and the bearing 133 based on the power transmitted from the lever 146.

When the plate 131 is rotated, the rotational force of the plate 131 is transmitted to the first coupling part 135 through the second coupling part 136 and the first link 137. At this time, the first coupling portion 135 rotates in the left and right directions while being vertically disposed. As a result, the shaft 122 rotates so that the inlet guide vane 120 rotates at a certain angle.

As a result, by a control system (not shown), the power provided from the cylinder 150 is transmitted to the drive unit 130 through the lever unit 140, converted into rotational force in the drive unit 130, and transmitted to the shaft 122. As a result, the inlet guide vane 120 can be rotated and its angle can be adjusted according to the flow rate.

Although an embodiment of the present invention has been described above, the spirit of the present invention is not limited to the embodiment presented in the present specification, and those skilled in the art who understand the spirit of the present invention can add components within the scope of the same spirit. , other embodiments can be easily proposed by change, deletion, addition, etc., but this will also be said to be within the scope of the present invention.

100: Vibration damping device for axial flow pump
110: suction casing 112: through hole;
114: first side 115: first slope
116: second side 117: second slope
118: outer peripheral surface 119: extension part
120: Inlet guide vane 122: Shaft
124: groove part 130: driving part
131: plate 132: support pin
133: bearing 134: blocking plate
135: first coupling portion 136: second coupling portion
137: first link 140: lever part
142: shaft portion 144: third coupling portion
146: Lever 148: Second link
150: Cylinder 10: Impeller

Claims (5)

A suction casing provided in a cylindrical reel shape and having a through hole on the inside;
an inlet guide vane provided with a shaft on one side and the shaft disposed in the through hole; and
a driving unit provided along the outer periphery of the suction casing, connected to the shaft, and driven to adjust the angle of the inlet guide vane;
A vibration damping device for an axial flow pump including a. According to paragraph 1,
The shaft is a vibration damping device for an axial flow pump, wherein the shaft is provided inside the inlet guide vane in a fluid inflow direction. According to paragraph 1,
The driving unit,
a ring-shaped plate disposed on the outer periphery of the suction casing;
a support pin fixed to one surface of the suction casing and rotatably supporting the ring-shaped plate;
a bearing provided at an end of the support pin and rotating according to the movement of the plate;
a blocking plate covering the through hole with the shaft exposed to the outside;
a first coupling portion axially coupled to the shaft to rotate the shaft;
a second coupling portion vertically coupled to the plate; and
A first link connecting the first coupling portion and the second coupling portion to transmit the rotational force of the plate to the shaft;
A vibration damping device for an axial flow pump including a. According to paragraph 3,
It further includes a lever unit coupled to the plate to rotate the plate,
The lever part,
a shaft portion fixed to one surface of the suction casing;
a third coupling part vertically coupled to the plate;
An L-shaped lever rotatably coupled to the shaft portion; and
a second link connecting the lever and the third coupling portion to transmit the rotational force of the lever to the plate;
A vibration damping device for an axial flow pump including a. According to clause 4,
Further comprising a cylinder that provides power to the driving unit,
The cylinder is a vibration damping device for an axial flow pump connected to the lever.

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