JP2011231777A - Pump - Google Patents

Abstract

PROBLEM TO BE SOLVED: To positively cool a mechanical seal part without carrying out unnecessary piping.SOLUTION: In the pump including a casing 10 formed in the interior with a suction chamber 21 communicated with a suction port 14a and a discharge chamber 22 communicated with a discharge port 15a, an impeller 24 connected to a rotary shaft 27 piercing the casing 10 and disposed in the discharge chamber 22, and the mechanical seal part 31 disposed in a portion of the casing 10 pierced by the rotary shaft 27, a recirculation passage 37 recirculating a fluid is provided in the casing 10 such that an inlet 37a is positioned near the mechanical seal part 31 and an outlet 37b is positioned in a low pressure area of an upstream side of the suction chamber 21 lower than a flow pressure of the inlet 37a, a flow suppressing part 36 projecting toward the rotary shaft 27 is provided on an inner wall of the casing 10, and the outlet 37b of the recirculation passage 37 is opened in the low pressure area formed in a liquid flow direction end by the flow suppressing part 36.

Description

  The present invention relates to a rotary pump of an impeller such as a double suction centrifugal pump, a double suction mixed flow pump, a single suction centrifugal pump, a single suction mixed flow pump, a multistage pump and a multistage turbine pump. The present invention relates to a pump that discharges by flowing in an orthogonal direction.

  In this type of pump, the other end of a rotating shaft having one end connected to a prime mover is inserted or penetrated into a casing, and an impeller is disposed on the rotating shaft. When the impeller is rotated by driving the prime mover, the pump sucks liquid from the suction port of the casing and discharges the liquid from the discharge port through the spiral chamber that houses the impeller.

  Moreover, this pump forms the mechanical seal part in the support part of the casing in order to prevent the liquid whose pressure is increased by the flow from leaking out from the gap between the casing and the rotating shaft. However, since this mechanical seal part generates heat by sliding contact, it needs to be cooled.

  Accordingly, there is a type in which a through hole is provided so as to be positioned at a mechanical seal portion of the suction pump, and water is supplied from the through hole at a predetermined pressure. However, this self-flushing pump needs to be provided with a pressure reducing mechanism using an orifice or a valve, and there is a problem that the structure is complicated and the cost is high. In addition, it is extremely difficult to adjust the flushing flow rate.

  On the other hand, Patent Document 1 describes a cooling structure for a mechanical seal portion that uses a liquid that passes through a balance hole formed in an impeller in a single suction centrifugal pump.

  However, the cooling structure disclosed in Patent Document 1 cannot stably supply liquid. That is, the pressure in the casing is different even if the distance from the rotating shaft is the same. Therefore, since the liquid flow through the balance hole is not stable, a stable cooling action cannot be obtained.

  Further, Patent Document 2 describes a shaft seal device in which through holes are provided in the vicinity of a suction port of a casing and in a mechanical seal portion, a connecting pipe is piped over the through holes, and a liquid is caused to flow by a pressure difference. Yes.

  However, in the cooling structure of Patent Document 2, since it is necessary to connect a connecting pipe for reflux outside the pump, there is a problem that the number of parts increases and the cost increases. Moreover, since the connecting pipe is exposed to the outside, a useless arrangement space is required.

Japanese Utility Model Publication No. 5-12696 JP 2002-221189 A

  This invention is made | formed in view of the conventional problem, and makes it a subject to provide the pump which can cool a mechanical seal part reliably, without performing unnecessary piping.

  In order to solve the above problems, a pump according to the present invention is connected to a casing in which a suction chamber communicating with a suction port and a discharge chamber communicating with a discharge port are formed, and a rotary shaft penetrating the casing. Arranged in the discharge chamber, the inlet is located at the connecting portion to the rotating shaft, the outlet is located at a portion through which the rotating shaft of the casing penetrates, and the impeller located radially outside the rotating shaft. A mechanical seal portion, wherein the suction port opens in a direction orthogonal to the extending direction of the rotation shaft, and the blade sucks the suction suction from the suction port with respect to the rotation shaft. In the pump that discharges from the outlet of the impeller through the discharge chamber and the discharge port after being guided to the inlet of the vehicle, an inlet is located in the casing in the vicinity of the mechanical seal portion. In addition to providing a reflux path for refluxing the liquid so that the outlet is located in a low pressure region upstream of the suction chamber, a flow suppression portion that protrudes toward the rotating shaft is provided on the inner wall of the casing. The outlet of the reflux path is opened in a low pressure region formed ahead of the liquid flow direction by the suppressing portion.

  According to this pump, the casing is provided with a reflux path in which the inlet is located in the mechanical seal portion and the outlet is located in the low pressure region on the upstream side where the flow pressure is lower than the inlet. With this, the mechanical seal can be reliably cooled. And since the reflux path is provided in the fixed casing, the pressure in an exit can be stabilized. As a result, a stable reflux action can be obtained. In addition, since the flow suppressing portion is provided on the inner wall of the casing so that the low pressure region can be reliably formed in the suction chamber, the recirculation action due to the differential pressure can be obtained more reliably. Furthermore, since the reflux path can be formed by only partially adding the structure of the existing mechanical seal portion and no additional parts such as a connecting pipe are required, an increase in cost can be prevented. In addition to the self-flushing mechanism, there is no extra connecting pipe that protrudes to the outside.

  In this pump, it is preferable that a stirring blade for providing a radially outward water flow is disposed on the rotating shaft of the impeller. If it does in this way, forced water flow (refluxing action) can be generated at a predetermined pressure from the mechanical seal part to the upstream side of the suction chamber via the reflux path. Therefore, especially when the liquid contains foreign matter, the foreign matter can be reliably removed to the upstream side of the suction chamber.

  In the pump of the present invention, since the pressure at the outlet of the reflux path can be stabilized, a stable reflux action can be obtained, and the mechanical seal portion can be reliably cooled. Further, since no additional parts such as a connecting pipe are required, an increase in cost can be prevented and a useless installation space is unnecessary.

It is sectional drawing which shows the pump of 1st Embodiment of this invention. It is the schematic which shows a double suction type centrifugal pump. It is sectional drawing which cut | disconnected the other position of FIG. It is a principal part expanded sectional view of FIG. It is a halftone image which shows the pressure distribution of the pump of FIG. The stirring blade is shown, (A) is a perspective view, (B) a side view, and (C) is a sectional view. It is a halftone image which shows the pressure distribution of the pump of 2nd Embodiment. It is a graph which shows the pressure and lubricating water amount by the pump of FIG.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 shows a horizontal suction double-suction centrifugal pump that is an example of a pump according to a first embodiment of the present invention. This both suction type centrifugal pump forms the suction chamber 21 and the discharge chamber 22 in the casing 10, and sucks the liquid from the suction port 14a by rotationally driving the impeller 24 disposed in the discharge chamber 22. The liquid is guided to the discharge chamber 22 while being swung with respect to the rotation shaft 27 of the impeller 24 and discharged from the discharge port 15a.

  In the present embodiment, the casing 10 is provided with a reflux path 37 extending from the mechanical seal portion 31 toward the upstream side of the suction chamber 21, and by the reflux action due to the differential pressure through the reflux path 37, The mechanical seal portion 31 is cooled by the liquid that is sent out.

  Specifically, the casing 10 includes an upper casing 11 and a lower casing 12. As schematically shown in FIG. 2, the casing 10 includes a suction pipe portion 14 so as to protrude from both sides of the lower portion of the central liquid swiveling portion 13, that is, the front and rear of the lower casing 12. The discharge pipe portion 15 is integrally formed. The suction pipe portion 14 is provided so as to communicate only with a suction chamber 21 described later, and the discharge pipe portion 15 is provided so as to communicate only with a discharge chamber 22 described later.

  As shown in FIG. 1, inside the casing 10, a pair of upper partition walls 17 and 17 are provided at the center in the width direction of the upper casing 11, and a pair of lower partition walls at the center in the width direction of the lower casing 12. 18 and 18 are provided. The partition walls 17 and 18 are provided with a communication port portion 19 having a circular shape in the assembled state so that the position slightly biased upward is the center. A bearing is disposed on the inner periphery of the communication port 19. Further, as shown in FIG. 3, the lower partition walls 18, 18 are closed by the closing wall 20 at the end portions that appear in a state facing the suction pipe portion 14. FIG. 3 shows a state cut along the flow line of the liquid flowing from the suction pipe portion 14 to the communication port portion 19.

  The casing 10 constitutes a suction chamber 21 in which the outer regions of the partition walls 17 and 18 that are continuous with the inside of the suction pipe portion 14 form a spiral shape, and the partition wall 17 that is continuous with the suction chamber 21 via the communication port portion 19. , 18 constitute a discharge chamber 22 having a symmetrical spiral shape. The discharge chamber 22 is provided so as to communicate with the discharge pipe portion 15. The discharge chamber 22 is further divided into an inner discharge chamber 15 a and an outer discharge chamber 22 b by providing a partition plate 23 between the lower partition walls 18, 18 of the lower casing 12.

  An impeller 24 including a centrifugal impeller having a plurality of blades is rotatably disposed inside the discharge chamber 22. The impeller 24 sucks liquid from the suction port 14a that is the open end of the suction pipe portion 14 by rotation, and passes the liquid from the discharge port 15a that is the open end of the discharge pipe portion 15 through the suction chamber 21 and the discharge chamber 22. A water flow for discharging is formed. At the center of the impeller 24, a connecting portion 25 is provided which is fitted in a bearing of the communication port portion 19 of the casing 10 and is connected to the rotating shaft 27 so as to be relatively rotatable. Further, the blades of the impeller 24 are provided such that the inlet 26 a is located at the connecting portion 25 and the outlet 26 b is located radially outside the rotation shaft 27.

  The rotating shaft 27 of this embodiment is arrange | positioned so that the casing 10 may be penetrated, and the impeller 24 is connected to the intermediate position. The rotating shaft 27 is disposed so as to extend in a direction orthogonal to the axial direction of the suction pipe portion 14 provided with the suction port 14a. The rotating shaft 27 is rotatably supported by bearing brackets 28 </ b> A and 28 </ b> B provided on both sides of the casing 10. The bearing bracket 28 </ b> A supports the end portion of the rotating shaft 27 while being accommodated. Further, the bearing bracket 28B supports the rotating shaft 27 in a state in which it passes through. The end of the rotating shaft 27 that passes through the bearing bracket 28B is connected to a motor (not shown).

  In addition, the casing 10 is provided with support portions 29 for rotatably supporting the rotary shaft 27 at both side portions through which the rotary shaft 27 passes. These support portions 29 and 29 are provided so as to coincide with the center of the communication port portion 19. In the present embodiment, the upper casing 11 and the lower casing 12 are separately molded at the positions of the support portions 29 and 29. Therefore, each support part 29 and 29 is comprised by forming a semi-cylindrical part in each casing 11 and 12. FIG. The support portion 29 includes a bulging portion 30 that bulges into the suction chamber 21 along the axial direction of the rotating shaft 27. The inner diameter of the support portion 29 is larger than the outer diameter of the rotating shaft 27, and the tip opening of the bulging portion 30 communicates with the suction chamber 21 in the casing 10.

  Inside the support portion 29, a mechanical seal portion 31 that supports the rotary shaft 27 so as to be rotatable while being sealed is disposed. As shown in FIG. 4, the mechanical seal portion 31 is disposed between a base 32 that is closely fixed to the rotary shaft 27, a drive ring 33 that is rotatably disposed on the outer peripheral portion of the base 32, and a gap therebetween. A seal ring 34 and a rotary ring 35 are provided.

  Further, as shown in FIG. 2, the casing 10 is provided with a flow suppressing portion 36 that protrudes toward the rotating shaft 27. The flow suppressing part 36 is provided so as to be inclined downward from the upper casing 11 so as to be located in the most downstream area in the suction chamber 21. As shown in the figure, the flow suppressing portion 36 is provided integrally with the upper casing 11 or provided as a separate plate so as to extend in the radial direction toward the rotating shaft 27. It is formed by.

  In the present embodiment, a reflux path 37 extending toward the upstream side of the suction chamber 21 is provided in the support portion 29 provided with the mechanical seal portion 31. The reflux path 37 is provided such that its inlet 37a is positioned in the vicinity of the mechanical seal portion 31, and its outlet 37b is positioned in an upstream low pressure region lower than the flow pressure of the inlet 37a. Further, the reflux path 37 is formed by providing a through hole in the wall of the bulging portion 30 of the support portion 29 so as to extend in a direction orthogonal to the rotation shaft 27. The reflux path 37 is not limited to a method formed at the time of new manufacture of the pump, and can be formed by performing additional processing on the existing pump later.

  Here, the pressure distribution in the suction chamber 21 due to the suction of the liquid from the suction port 14a of the casing 10 by the impeller 24 is shown in FIG. The halftone image displayed on the display of FIG. 5 is submitted as a reference color image 1 in the property submission form. As shown in this figure, the pressure due to the liquid flowing in the suction chamber 21 gradually increases from the suction port 14 a side toward the communication port portion 19. And it becomes high gradually toward the inner wall of the casing 10 around the rotating shaft 27. This is because the liquid in the suction chamber 21 flows into the discharge chamber 22 from the communication port portion 19. And since the flow suppression part 36 is provided in the casing 10 of this embodiment, seeing from the extension direction of the rotating shaft 27, it turns and flows counterclockwise toward the flow suppression part 36, and the flow suppression part Most of the liquid that has collided with 36 is guided from the inlet 26 a of the impeller 24 to the discharge chamber 22. As a result, a low pressure region having a low flow pressure is formed in the liquid flow direction ahead of the flow suppression unit 36, which is the counterclockwise direction. However, since the flow of the liquid is suppressed (blocked) before the flow suppressing unit 36 in the liquid flow direction, the flow pressure becomes high. Therefore, in the present embodiment, the reflux path 37 is provided so that the inlet 37a is located in the vicinity of the extension line in the extending direction of the flow suppressing portion 36, and the outlet 37b is formed in the liquid flow direction ahead of the flow suppressing portion 36. It is provided so as to be located in the pressure region.

  Further, as shown in FIGS. 1 and 4, the rotating shaft 27 of the present embodiment is provided with a water flow outward in the engagement direction in the support portion 29 so as to be positioned in the vicinity of the mechanical seal portion 31 of the casing 10. A stirring blade 38 is provided. As shown in FIGS. 6 (A), 6 (B), and 6 (C), the stirring blade 38 is provided with a blade portion 40 that protrudes in a flange shape at one end of a cylindrical mounting portion 39. is there. The blade portion 40 has an annular shape, and a stirring groove 41 is provided on the outer peripheral portion thereof at a predetermined interval in the circumferential direction. The stirring groove 41 is provided so as to extend over the outer peripheral edge of the blade portion 40. Further, a packing arrangement groove 42 is provided on the inner peripheral portion of the mounting portion 39. Further, the mounting portion 39 is provided with an insertion hole 43 that penetrates inside and outside, and is tightened with a screw with respect to the rotary shaft 27 through the insertion hole 43 so that it cannot move relative to the rotary shaft 27. Linked in state. Note that the liquid flows into the support portion 29 along the rotation shaft 27 from the tip opening of the bulging portion 30. Therefore, the stirring blade 38 is mounted so that the stirring groove 41 is located on the side of the front end opening of the bulging portion 30.

  In the pump configured as described above, when the impeller 24 is rotated via the rotation shaft 27 by driving the prime mover, the liquid flows in from the suction port 14a of the suction pipe portion 14, and in the liquid swirling portion 13 having a circular shape, The liquid flows while swirling around the rotation shaft 27. Then, the liquid is sucked from the inlet 26 a of the impeller 24 around the rotation shaft 27, ejected from the outlet 26 b into the discharge chamber 22, and then discharged from the discharge port 15 a of the discharge pipe portion 15.

  At this time, in the present embodiment, the support portion 29 on which the mechanical seal portion 31 is disposed is provided so as to communicate with the suction chamber 21. The support portion 29 is provided with a reflux path 37 so that the outlet 37b is located in a low pressure region lower than the flow pressure inside (inlet 37a). Therefore, due to the differential pressure between the inlet 37a and the outlet 37b, a part of the liquid located around the communication port portion 19 flows into the support portion 29 from the opening of the support portion 29 as shown by an arrow in FIG. Then, it is refluxed to the upstream side of the suction chamber 21 through the reflux path 37. And since the reflux path 37 is provided in the fixed casing 10, the pressure in the exit 37b does not physically fluctuate. Therefore, it is possible to stably obtain the reflux action shown in FIG. As a result, the mechanical seal 31 that generates heat by use can be reliably cooled.

  In the present embodiment, since the stirring blade 38 is provided in the support portion 29 so as to be positioned in the vicinity of the mechanical seal portion 31, the liquid in the support portion 29 is directed radially outward with respect to the rotation shaft 27. Water flow toward is provided. The reflux path 37 is provided so as to extend in the orthogonal (diameter) direction with respect to the rotation shaft 27. Therefore, the liquid is forced to flow upstream through the reflux path 37 by the water flow generated by the stirring blade 38. Therefore, when a foreign substance is contained in the liquid, the foreign substance can be reliably removed to the upstream side of the suction chamber 21, and the accumulation of the foreign substance on the mechanical seal portion 31 can be prevented. Moreover, the flow pressure at the inlet 37a is reliably higher than the outlet 37b of the reflux path 37. Therefore, even if a manufacturing error of the reflux path 37 with respect to the casing 10 or a pressure fluctuation caused by the amount of liquid to be sent out occurs, a reflux action can be reliably obtained, and cooling of the mechanical seal portion 31 can be realized.

  Furthermore, in this embodiment, since the flow suppression part 36 is provided in the casing 10, the area | region where a flow pressure differs with respect to this flow suppression part 36 before and behind a liquid flow direction can be formed. Therefore, it is possible to reliably set the outlet 37b of the reflux path 37 and reliably obtain the reflux action due to the differential pressure. In addition, the reflux path 37 can be formed by only partially performing an additional process on the structure of the existing mechanical seal portion 31, and additional parts such as a connecting pipe are not necessary, thereby preventing an increase in cost. Moreover, since there is no extra connecting pipe protruding outside, no unnecessary installation space is required.

  FIG. 7 shows the pressure distribution of the pump of the second embodiment. The halftone image displayed on the display of FIG. 7 is submitted as a reference color image 2 in the property submission form. The second embodiment is different from the first embodiment in that the flow suppressing portion 36 is provided so as to be inclined obliquely upward from the lower casing 12. Even in this case, as shown in the drawing, it is possible to form a low pressure region with a low flow pressure in front of the flow suppressing portion 36 in the liquid flow direction. Therefore, similarly to the first embodiment, the liquid around the rotating shaft 27 is sucked into the support portion 29, and the reflux action flows from the inlet 37a to the upstream side of the suction chamber 21 from the inlet 37a through the reflux path 37. Obtainable. Therefore, the mechanical seal part 31 can be reliably cooled.

The present inventors conducted experiments using the pump shown in the first embodiment in order to confirm the effects of the configuration of the present invention. In this experiment, a flow meter is installed to measure the flow rate in the reflux path 37, and pressure sensors are installed in the vicinity of the outer periphery of the stirring blade 38, the inlet 37a of the support 29, and the outlet 37b of the reflux path 37, The pressure kgf / cm ² and the amount of lubricating water 1 / hr at a predetermined site were measured in the operating state of the pump that rotated the prime mover at 1000 min ⁻¹ and delivered 8000 L / min of liquid from the discharge port 15 a.

  As shown in FIG. 8, the pressure P1 at the outer periphery of the stirring blade 38 is higher than the pressure P2 in the support 29 (inlet 37a), and the pressure P3 in the vicinity of the outlet 37b of the reflux path 37 is higher than this pressure P2. It becomes. The amount of lubricating water is such that the amount of water on the thrust bearing (bearing bracket 28A) side is greater than the amount of water on the coupling (bearing bracket 28B) side. Therefore, in this pump, it has been confirmed that it is possible to obtain a reflux action in which the liquid flows into the support portion 29 from the opening of the support portion 29 and flows from the inlet 37a to the outlet 37b of the reflux path 37.

  In addition, the pump of this invention is not limited to the structure of the said embodiment, A various change is possible.

  For example, in the above-described embodiment, the balance type stirring blade 38 having the blade portion 40 provided with the stirring groove 41 at equal intervals is disposed in the support portion 29, but the blade portion 40 provided with the stirring groove 41 unevenly. It is good also as a structure which arrange | positions the unbalanced type stirring blade 38 which has these. Moreover, in the said embodiment, although the flow suppression part 36 was provided in the casing 10, the structure which does not provide this flow suppression part 36 may be sufficient. And it is preferable to change the shape (for example, stirring groove 41) of this stirring blade 38 according to the flow volume required for recirculation | reflux.

  Furthermore, in the said embodiment, although the structure which provides the reflux path 37 of this invention as a pump in both suction type centrifugal pumps was employ | adopted, a double suction type mixed flow pump, a single suction type centrifugal pump, a single suction type mixed flow pump, a multistage Even pumps such as pumps and multi-stage turbine pumps can be applied in the same manner, and similar actions and effects can be obtained. That is, any support can be applied as long as the support portion 29 of the rotating shaft 27 on which the mechanical seal portion 31 is disposed is a pump communicating with the suction chamber 21 in the casing 10.

DESCRIPTION OF SYMBOLS 10 ... Casing 14a ... Suction port 15a ... Discharge port 19 ... Communication port part 21 ... Suction chamber 22 ... Discharge chamber 24 ... Impeller 25 ... Connection part 26a ... Inlet 26b ... Outlet 27 ... Rotating shaft 29 ... Support part 30 ... Swelling Part 31 ... Mechanical seal part 36 ... Flow suppression part 37 ... Reflux path 37a ... Inlet 37b ... Outlet 38 ... Stirring blade

Claims (2)

A casing in which a suction chamber communicating with the suction port and a discharge chamber communicating with the discharge port are formed;
An impeller that is connected to a rotating shaft that penetrates the casing and is disposed in the discharge chamber, an inlet is located at a connecting portion to the rotating shaft, and an outlet is located radially outside the rotating shaft; ,
A mechanical seal portion disposed in a portion through which the rotating shaft of the casing passes,
The suction port opens in a direction orthogonal to the direction of extension of the rotating shaft, and the suction chamber guides the liquid sucked from the suction port to the inlet of the impeller while turning with respect to the rotating shaft. After, in the pump that discharges from the outlet through the discharge chamber from the outlet of the impeller,
In the casing, an inlet is located in the vicinity of the mechanical seal portion, and a reflux path for refluxing the liquid is provided so that the outlet is located in a low pressure region upstream of the suction chamber lower than the flow pressure of the inlet.
Provided on the inner wall of the casing is a flow suppressing portion that protrudes toward the rotating shaft, and the outlet of the reflux path is opened in a low pressure region that is formed forward of the liquid flow direction by the flow suppressing portion. And pump.   The pump according to claim 1, wherein a stirring blade that imparts a radially outward water flow is disposed on a rotation shaft of the impeller.