JP2895180B2 - Single mechanical seal type pump - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to a single mechanical seal type pump which can prevent leakage of cooling water, and more specifically, an outside single mechanical seal type which seals outside a pump body. Related to pumps.

[Problems to be Solved by the Related Art and the Invention] In the chemical industry and the like, when supplying a corrosive liquid, for example, an acid such as hydrochloric acid or sulfuric acid, or an alkaline aqueous solution such as sodium hydroxide, etc. High ceramic pumps are used.

FIG. 3 is a schematic sectional view showing a ceramic pump as a conventional single mechanical seal type pump.

The ceramic pump includes a motor (not shown), a shaft (31) attached to a rotating shaft (not shown) of the motor, a bearing (32) rotatably supporting the shaft (31), A sleeve (33) fitted to the shaft (31).

Also, the shaft (31) is inserted into the sleeve (33),
A stationary ring (34) attached to the casing is located outside the sleeve (33). This fixed ring (34)
The liquid which is pressed by the rotating ring (35) and flows from the gap between the fixed ring (34) and the sleeve (33) is sealed. That is, the rotating ring (35) includes a first rotating ring (35a) that presses the fixed ring (34) and the first rotating ring (35a).
A second rotating ring (35b) disposed outside the side of the first rotating ring (35b), and a spring (36) connecting the first rotating ring (35a) and the second rotating ring (35b). Have been.

In order to cool the sliding contact portion between the fixed ring (34) and the rotating ring (35), a cover (38) provided outside the fixed ring (34) and the rotating ring (35) is provided. A cooling water channel (37) is formed. The cooling water supplied from the cooling water channel (37) is discharged through a cooling water receiving portion (39) formed at a lower portion of the cover (38) and a pipe portion (40) for connecting a hose. You.

A casing (42) is attached to the fixed ring (34) via a fixed ring pressing member (41). The casing (42) has an inlet (43) through which a liquid flows,
A discharge port (44) for discharging a liquid is formed. Also,
An impeller (45) is attached to the tip of the shaft (31) reaching the inside of the casing (42). A pump body is composed of the casing (42) and the impeller (45) at the tip of the shaft (31).

The liquid contact part of the pump, that is, the fixed ring (34), the inner surface of the casing (42), and the impeller (45) are formed of ceramic.

In such a ceramic pump, the impeller (45) is rotated by a motor and the inlet (4) of the casing (42) is rotated.
The corrosive liquid flowing in from 3) can be discharged from the discharge port (44). In addition, the fixed ring (3
4) Apply the pressing force of the rotating ring (35) to the fixed ring (34).
And the rotating ring (35) can be sealed, and the sliding contact between the stationary ring (34) and the rotating ring (35) located outside the pump body is supplied from the cooling water flow path (37). Cooling water.

However, in the ceramic pump having such a structure, when cooling water is supplied to the sliding contact portion between the fixed ring (34) and the rotating ring (35), the fixed ring (35) rotates with the rotation of the rotating ring (35). Cooling water splashes around the pump from between 35) and the cover (38). And when the cooling water scatters, the floor around the pump corrodes and the installation floor becomes slippery.
The working environment decreases.

In order to prevent the cooling water from scattering, it is also possible to provide an oil seal between the rotating ring (35) and the cooling water cover (38). However, in this case, not only the structure becomes complicated, but also the rotating ring (35) and the sealing member are in sliding contact with each other. Therefore, the scattering of the cooling water cannot be prevented for a long time due to the wear of the seal member. Such a problem occurs not only in the above-mentioned ceramic pump but also in an outside single mechanical seal type pump using stainless steel or the like.

SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a single mechanical seal type pump that has a simple structure and can surely prevent scattering of cooling water.

[Means for Solving the Problems] In order to achieve the above object, the present invention provides a shaft driven to rotate, a sleeve in which the shaft is inserted, and a fixed member attached to a casing and located outside the sleeve. A ring, a rotating ring slidably provided on the sleeve and urged against the fixed ring, an impeller mounted on the shaft, and an impeller for accommodating the impeller and mounted on the fixed ring. A pump having a casing having an inlet and an outlet, and a cooling water supply path for supplying cooling water to a sliding portion between the rotating ring and the fixed ring, the groove having a groove in an inner circumferential direction. Provided is a single mechanical seal type pump in which an annular member is provided in a non-contact state with the rotating ring.

[Operation] In the single mechanical seal type pump of this structure,
When cooling water is supplied from the cooling water supply path to the sliding contact portion between the rotating ring and the fixed ring, scattering of the cooling water accompanying the rotation of the rotating ring causes grooves formed in the circumferential direction of the inner surface of the annular member. Is suppressed.

In addition, since the annular member is mounted in a non-contact state with the rotating ring, the inner surface of the annular member is not worn, and the scattering of the cooling water can be prevented for a long time.

Embodiment An embodiment of the present invention will be described below in detail with reference to the accompanying drawings.

FIG. 1 is a schematic sectional view showing an embodiment of a ceramic pump as a single mechanical seal type pump of the present invention, and FIG. 2 is a sectional view of a first essential part.

The ceramic pump includes a rotating shaft (1) rotated by an electric motor (not shown) such as a motor, and the rotating shaft (1).
Shaft (3) connected to coupling (2)
And a bearing (4) that rotatably supports the shaft (3).
a) and (4b). A ceramic sleeve (5) is fitted into the shaft (3), and a casing (18) is attached to the outside of the sleeve (5), and steps are formed in both circumferential directions. A ceramic retaining ring (6) is located. The fixed ring (6) is pressed by a rotating ring (7) rotatably provided on the sleeve (5). That is, the rotary ring (7) is disposed slidably in the axial direction of the sleeve (5), and presses the fixed ring (6).
a), and a second rotating ring (7) disposed outside the side of the first rotating ring (7a) and restricted from moving in the axial direction.
b) and a spring (8) connecting the first rotating ring (7a) and the second rotating ring (7b). Therefore,
The first rotating ring (7a) is pressed against the fixed ring (6) by using the biasing force of the spring (8) to form a seal portion of the single mechanical seal type pump. That is, the liquid flowing from the gap between the stationary ring (6) and the sleeve (5) can be sealed between the solid ring (6) and the first rotating ring (7a).

On the other hand, when the first rotating ring (7a) rotates in contact with the stationary ring (6), the temperature increases due to frictional heat of the sliding contact portion. Then, in order to cool a sliding contact portion between the stationary ring (6) and the rotating ring (7), a cover member (10) provided outside the stationary ring (6) and the rotating ring (7). A cooling water flow path (9) is formed toward the sliding contact portion.

The cover member (10) is provided with a Teflon labyrinth packing (12) as an annular member having a spiral groove (11) formed on the inner peripheral surface, outside the rotary ring (7), that is, the rotary ring. It is mounted in a non-contact state with (7).

In this example, a groove (13) is formed in the valley of the spiral groove (11) in the direction of the opening of the labyrinth packing (12), and the groove (13) is formed on the end face of the labyrinth packing (12). It leads to a hole.

The lower part of the cover member (10) is formed in a Y-shaped cross section. That is, a cooling water receiving portion (14) is provided below the cover member (10) to discharge the cooling water.
And a pipe portion (15) for hose connection communicating with the bottom of the receiving portion (14). The cooling water from the cooling water channel (9) is guided to the receiving portion (14), and is discharged through a hose connected to the pipe portion (15).

From the cooling water flow path (9), a stationary ring (6) and a rotating ring (7)
When the cooling water is supplied to the sliding portion of the labyrinth packing, the spiral groove (11) for suppressing the scattering of the cooling water to the outside is formed on the inner peripheral surface of the labyrinth packing (12). Without being scattered to the outside, it is guided along the spiral groove (11) to the receiving portion (14) and the pipe portion (15) and is discharged.

Further, an impeller (17) is attached to the tip of the shaft (3) via an O-ring (16). A casing (18) for accommodating the impeller (17) is provided on the fixed ring (6) via a fixed ring pressing member (21).
The casing (18) is provided with an inflow port (19) through which a fluid flows in and a discharge port (20) for discharging a liquid, thereby constituting a spiral pump.
The pump main body is constituted by the impeller (17) and the casing (18). In addition, the liquid contact portion of the pump, that is, the inner surfaces of the impeller (17) and the casing (18) are formed of ceramic. Further, the fixed ring (6)
Are sealed by gaskets (22a) (22b).

In such a ceramic pump, an annular labyrinth packing (12) has a spiral groove (11) on its inner peripheral surface,
In addition, since the packing (12) is mounted in a non-contact state with the rotating ring (7), scattering of the cooling water can be prevented without abrasion of the packing (12). In addition, when the present inventors attached the labyrinth packing (12) to the cover member (10) and supplied cooling water to the conventional ceramic pump, and operated for about one month, the cooling water was completely scattered. It was confirmed that one drop did not leak from the drain hole on the end face of the labyrinth packing (12).

In order to prevent the cooling water from scattering, the present invention is not limited to the labyrinth packing (12), but may be any annular member having a groove formed in the inner circumferential direction. The groove of the annular member may be a groove that is discrete in the inner circumferential direction, but is preferably an annular groove or a spiral groove formed in the inner surface in the circumferential direction. When the annular member has an annular groove or a spiral groove on the inner peripheral surface, the number of peaks, the pitch and the height of the peaks can be selected according to the supply speed of the cooling water, but at least five peaks are formed. Is preferred. Also, the pitch of the annular groove is 2-3mm, the height of the mountain is 2-3mm
It is preferred to be on the order of magnitude. The material of the annular member is not limited to Teflon, but may be plastic, ceramic, metal, or the like.

The annular member only needs to have its groove facing the rotary ring and attached in a non-contact state, and the attachment location is not limited to the cover member.

Further, the fixed ring pressing member may be formed integrally with the cover member.

In the illustrated example, the groove (1) reaching the drain hole on the end face of the labyrinth packing (12) is formed in the valley of the spiral groove (11).
Although 3) is formed, this groove (13) is not always necessary.

Further, the present invention is not limited to the ceramic pump, as long as the stationary ring and the rotating ring are in sliding contact with the outside of the pump body, and the outside is a single mechanical seal type pump in which cooling water is supplied to the sliding contact portion. The present invention can be applied to any single mechanical seal type pump using stainless steel or the like, and the bearing, casing, and the like are not limited to the illustrated structure.

[Effect of the Invention] The single mechanical seal type pump of the present invention has a simple structure in which the annular member is mounted in a non-contact state with the rotating ring, and can reliably prevent the cooling water from scattering.

[Brief description of the drawings]

FIG. 1 is a schematic sectional view showing an embodiment of a ceramic pump as a single mechanical seal type pump according to the present invention, FIG. 2 is a sectional view of a first principal part, and FIG. 3 is a conventional single mechanical seal type pump. FIG. 1 is a schematic sectional view showing a ceramic pump as an example. (3) ... shaft, (5) ... sleeve, (6) ...
Fixed ring, (7) rotating ring, (8) spring, (9) cooling water flow path, (11) spiral groove, (12) labyrinth packing (annular member), ( 17) Impeller, (18) Casing, (19) Inflow port, (20) Discharge port

──────────────────────────────────────────────────続 き Continued on the front page (58) Field surveyed (Int. Cl. ⁶ , DB name) F04D 7/06 F04D 29/12 F04D 29/04 F16J 15/34

Claims (1)

(57) [Claims] A rotating shaft, a sleeve in which the shaft is inserted, a fixed ring attached to a casing and located outside the sleeve, and slidably provided on the sleeve; A rotating ring biased against a fixed ring, an impeller attached to the shaft,
A casing containing the impeller and attached to the stationary ring, having an inflow port and a discharge port, and a cooling water supply path for supplying cooling water to a sliding contact portion between the rotating ring and the stationary ring. A single mechanical seal type pump, wherein an annular member having a groove in an inner circumferential direction is provided in a non-contact state with the rotating ring.