JPH0738675U - Submersible pump device - Google Patents

Abstract

(57) [Summary] [Object] The present invention is to provide a submersible pump device which is inexpensive in cost and has a simple structure and which prevents sand contained in water from entering the electric motor unit. [Structure] A blade 40 for generating a water flow W to the surroundings as the output shaft 15 of the electric motor unit 3 rotates is provided on the outer peripheral surface of a sand guard collar 36 provided on the output shaft 15 of the electric motor unit 3. Provided. As a result, as the electric motor unit 3 rotates,
When 6 rotates, the sand S, which causes abrasion of the seal portion 38 of the color 36, is moved away from the color 36 by the water flow W generated by the centrifugal force of the blades 40.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a submersible pump device installed in a deep well or the like and pumping water from a state of being submerged in water.

[0002]

[Prior art]

 For the purpose of pumping fresh water, the submersible pump device used in a deep well or the like has a slender device body 1 extending in the vertical direction as a whole as shown in FIG. 3, and is composed of a strainer in the middle part. There is a pump device for fresh water, which has a suction port 2 as described above.

In the main body 1 of such a submersible pump device, an elongated hermetically sealed submersible electric motor unit 3 (hereinafter simply referred to as an electric motor unit 3) as shown in FIG. 4) is provided, and an elongated pump portion 4 as shown in FIG. 4 is provided on the upper side, and two shafts are coaxially connected inside the suction port 2.

That is, as shown in FIG. 5, the electric motor unit 3 is configured by providing an upper frame 7 and a lower frame 8 at both ends of a cylindrical cover 6 so as to close the opening. The casing 9 is provided with various elements of the electric motor.

Specifically, a rotating shaft 10 is provided in the casing 9 so as to extend in the vertical direction. A rotor 12 which is combined with a stator 11 installed on the inner surface of the cover 6 is provided at an intermediate portion of the rotary shaft 10.

The lower portion of the rotating shaft 10 is rotatably supported by a radial bearing portion 13 mounted on the lower frame 8, and the lower end portion is thrust on the lower frame 8. The bearing unit 14 supports the thrust.

The upper end of the rotating shaft 10 penetrates the upper frame 7 and projects to the outside. The protruding shaft end portion is used as the output shaft 15. The upper end portion is rotatably supported by a radial bearing portion 16 attached to the upper frame 7.

That is, the rotational force generated by the rotor 12 is transmitted to the output shaft 15. In FIG. 5, 11a indicates a can. On the other hand, the pump unit 4 has intermediate casings 17 stacked in a plurality of stages along the vertical direction as shown in FIG. A discharge casing 18 is provided on the upper side of the intermediate casing 17 and a suction casing 19 is provided on the lower side of the intermediate casing 17. The discharge casing 18, the intermediate casing 17, and the suction casing 19, which are arranged in series, are a plurality of bands 20 spanned between the discharge casing 18 and the suction casing 19 and are mutually connected. Are closely connected. Further, the discharge casing 18 is equipped with a valve casing 22 incorporating a discharge valve 21.

In the stacked intermediate casings 17, a main shaft 23 is arranged along the vertical direction so as to penetrate the intermediate casings 17. An upper portion of the main shaft 23 is rotatably supported by a radial bearing portion 24 incorporated in the discharge casing 18. The lower part extends to the inside of the suction casing 19. An impeller 25 rotatably incorporated in each intermediate casing 17 is attached to the outer peripheral portion of the main shaft 23. An opening 26 closed by a strainer is provided in a peripheral wall portion of the suction casing 19 arranged on the side of the main shaft 23, and the suction port 2 is formed in the same portion.

The lower end of the main shaft of the pump unit 4 and the output shaft 15 of the electric motor unit 3 are coaxially connected to each other via a joint 27, and further formed at the lower end of the suction casing 19 of the pump unit 4. The mounted seat 28 and the bolt 29 planted in the upper portion of the upper frame 7 of the electric motor unit 3 are fastened to each other with a nut 30 to form the apparatus body 1.

As a result, when the rotational force of the electric motor unit 3 is transmitted to the main shaft 23 of the pump unit 4 to drive the respective impellers 25, for example, the water in the well is formed around the output shaft 15, and the suction port is formed. 2 is pressure-fed to the discharge casing 18 through the respective intermediate casings 17 through a suction passage 31 connecting the suction casing 17a of the intermediate casing 17 at the lowest position. Then, this water is discharged through a discharge valve 21 of the valve casing 22 from a discharge port 32 provided at an upper end of the valve casing 22 and a water guiding pipe (not shown) connected to the discharge port 32. Through, it is pumped to a predetermined height.

By the way, the submersible pump device sucks not only fresh water but also solid matter such as sand S. Therefore, in the above-mentioned submersible pump device, the effect of sand is exerted on the portion between the output shaft 15 and the frame end of the electric motor unit 3 shown by the symbol A in FIG. A seal structure to avoid is taken.

Conventionally, in such a seal structure, as shown in an enlarged view in FIG. 6, among the through holes 33 through which the output shaft 15 penetrates, the inner peripheral surface serving as the frame end and the inner peripheral surface opposed thereto. A plurality of oil seals 34 are interposed as a seal member between the outer peripheral surface of the output shaft 15 and the sand S is collected at a portion outside the oil seal 34 in the same space. A filter 36 is provided, and in addition, the output shaft 15 is covered with a cover 36 so as to cover the surface of the exposed portion of the filter 35. Is being provided.

More specifically, an annular protrusion 37 is formed on the inner surface of the collar 36 so as to contact the exposed end surface of the filter 35 and seal. On the inner surface of the peripheral wall 36a of the collar 36, there is formed an annular convex portion 38 which comes into contact with the exposed outer peripheral surface of the filter 35 and seals. The protrusion 37 and the convex portion 38 form a filter. -35 is blocked to prevent sand from entering it.

[0015]

[Problems to be solved by the device]

 By the way, in the above-mentioned submersible pump device, most of the sand S contained in the water is pumped (sent) together with the water. At this time, since the seal portion including the convex portion 38 of the color 36 is exposed to the suction passage 31, if the submersible pump device is used for a long time, due to the influence of sand S contained in the water flow flowing around, The convex portion 36 in contact with the output shaft 15 may be abnormally worn.

This is because when the water is sent, a part of the sand S stagnates or gathers in the vicinity of the collar 36, and further, the sand S gathered around the collar 36 stops when the water is stopped. It is also due to the accumulation in the vicinity of 36.

The filter-35 collects the sand S that enters through the gap between the convex portion 36 and the filter-35 generated as described above. However, as is known, when the power source is turned on and off in the electric motor unit 3, the temperature inside the electric motor unit 3 changes, so that the sealed electric motor interior itself causes internal pressure fluctuation called breathing action.

Therefore, the fine sand S may pass through the filter 35 and reach the oil seal 34 due to the respiratory action. When this occurs, the oil seal 34 is also worn by the sand S, and the sand S enters the inside of the electric motor unit 3 through the gap formed between the oil seal 34 and the rotating shaft 10, causing a great problem. Will end up.

That is, the radial bearing portion 16 causes rattling such that the rotor 12 abuts the can 11a due to the ingress of the sand S, which may lead to invasion of water and cause insulation failure. .

Further, the thrust bearing portion 14a of the thrust bearing unit 14 may be worn, and the movement of the electric motor section 3 may be locked. As a countermeasure against this, recently, by increasing the number of oil seals 34, it is possible to prevent the sand S from entering the inside of the electric motor unit 3 and to provide a bearing that can withstand abrasion due to the sand S. It has been proposed to use high-grade materials such as ceramics.

However, all of them have a problem in that they are expensive, and they have not been put into practical use. The present invention has been made in view of such circumstances, and its purpose is to provide a solid structure such as sand contained in water into the electric motor section with a low cost and a simple structure. An object of the present invention is to provide a submersible pump device that can prevent the occurrence of the above.

[0022]

[Means for Solving the Problems]

 In order to achieve the above object, the submersible pump device according to claim 1 has a structure in which an output shaft of an electric motor unit rotates around an outer peripheral surface of a color for preventing intrusion provided on an output shaft of the electric motor unit. It has blades that generate water flow to the.

[0023]

[Action]

 In the submersible pump device according to claim 1, when the color rotates with the rotation of the electric motor part, a centrifugal force of the blades causes a water flow around the color to flow from the color toward the surroundings. To do.

As a result, solid matter such as sand, which causes abrasion, is kept away from the color. Therefore, abrasion of the seal portion of the color due to solid matter such as sand can be prevented. Therefore, intrusion of solid matter such as sand into the electric motor section due to wear of the color is prevented.

[0025]

【Example】

 The present invention will be described below based on an embodiment shown in FIGS. However, in the drawings, the same parts as those described in the above-mentioned "Prior Art" are designated by the same reference numerals, and the description thereof will be omitted. In this section, different parts (main parts of the invention) will be described. To do.

The present embodiment is different in that vanes 40 are provided on the outer peripheral surface of the color 36. That is, as shown in FIG. 1 and FIG. 2, for example, four ridges 40 are formed at the outer peripheral surface of the peripheral wall 36a of the collar 36, for example, in the vertical direction, at four even portions. Has been. In each of the blades 40, the upper end portion extends close to the upper surface of the collar 36, and the lower end portion extends to the same point as the lower end of the collar 36, for example.

With the installation of the blades 40, as the color 36 rotates, a water flow is generated around the color 36 from the color 36 toward the surroundings.

Next, the operation of the submersible pump device configured as described above will be described. For example, when the electric motor part 3 of the submersible pump device installed in the well is excited to pump water from the well, the rotor 12 rotates.

When the rotational force of the rotor 12 is transmitted from the output shaft 10 of the electric motor unit 3 to the main shaft 23 of the pump unit 3 via the joint 27, each intermediate casing 17 of the pump unit 3 is transmitted. The impeller 25 housed inside is driven to rotate.

As a result, the water in the well, together with the sand S (solid matter) contained in the water, passes from the suction port 2 through the suction passage 31 to the suction port 17a of the intermediate casing 17 at the lowest position. It is guided and pressure-fed by the impeller 25 to the intermediate casing 17 just above it. Furthermore, this water is pumped to the intermediate casing 17 immediately above by the impeller 25 housed in the intermediate casing 17.

In this way, the water is pressure-fed to the discharge casing 18 while sequentially passing through the intermediate casings 17. Then, this water is discharged through a discharge valve 21 of the valve casing 22 from a discharge port 32 provided at the upper end of the valve casing 22 and through a water pipe (not shown) connected to the discharge port 32. , Is pumped up to a predetermined height.

At this time, the collar 36 exposed in the suction passage 31 is rotated by the rotation of the output shaft 15. Here, the blades 40 present in the color 36 are rotating with the rotation of the output shaft 15, and the water flow W is generated around the color 36 by the centrifugal force of the blades 40 to move from the color 36 to the surroundings. Is being generated.

This means that solid matter such as sand S, which has been sucked together with water until it reaches the seal portion of the color 36, is always kept away from the color 36 by the water flow W.

Therefore, it becomes difficult for solid matter such as sand S to reach the seal portion of the color 36, and the seal portion of the color 36 caused by the solid matter, that is, especially the convex portion 38. It is possible to prevent wear of the.

As a result, the blades 40 are provided at a low cost and with a simple structure. Intrusion can be prevented.

Moreover, since solid matter such as sand S is splashed around the collar 36, even if the convex portion 38 of the collar 36 is worn, the solid matter such as sand S may enter the electric motor portion 3. Is suppressed and highly reliable.

Moreover, when the electric motor unit 3 is turned off, the sand S accumulated on the upper surface of the upper frame 7 is blown to the surroundings by the blade 40 each time the electric motor unit 3 is turned on. There is also an advantage that the influence of S on the electric motor unit 3 can also be avoided.

Although the blade 40 extended to the same position as the lower end of the collar 40 is used in one embodiment, the present invention is not limited to this, and the lower end of the collar 40 as shown by the chain double-dashed line in FIG. 1 is used. Alternatively, the blade 40 extending further downward may be used. By doing so, the gap between the color frame 40 and the upper surface of the upper frame 7 becomes smaller, so that there is no more solid material that faces the seal portion.

Further, the shape of the blade is not limited to a straight line, and may be a curved line, or may be a blade having an upper end on the upper surface of the color 40, in short, to generate a water flow from the color toward the surroundings. Any feather will do.

[0040]

[Effect of device]

 As described above, according to the present invention, it becomes difficult for solid matters such as sand to reach the seal portion of the color. As a result, with the inexpensive and simple structure of providing the blades, it is possible to prevent solid matter from entering the electric motor portion due to the abrasion of the seal portion of the color caused by the breathing action of the electric motor portion.

Moreover, since solid matter such as sand is splashed around the color, even if the seal part of the color is worn, entry into the electric motor section is suppressed and reliability is high. .

Further, when the electric motor unit is turned off, fixed objects such as sand accumulated at the frame end are splashed by the blades to the surroundings each time the electric motor unit is turned on. The influence of the electric motor section can be avoided.

[Brief description of drawings]

FIG. 1 is a sectional view illustrating an essential part of a submersible pump device according to an embodiment of the present invention.

FIG. 2 is a perspective view showing a structure around a color of the main part.

FIG. 3 is a perspective view showing the appearance of a submersible pump device for fresh water together with the configuration.

FIG. 4 is a cross-sectional view for explaining the structure of a pump section of the submersible pump device.

FIG. 5 is a cross-sectional view for explaining the structure of an electric motor section of the submersible pump device.

FIG. 6 is an enlarged cross-sectional view for explaining the seal structure of the color shown by the portion A in FIG.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Device main body 2 ... Suction port 3 ... Underwater electric motor part 4 ... Pump part 7 ... Upper frame 15 ... Output shaft 34 ... Oil seal (seal member) 35 ... Filter-36 ... Color 37 ... Projection piece (Seal part) 38 ... Convex part (seal part) 40 ... Blade

Claims (1)

[Scope of utility model registration request] 1. A periphery of an output shaft of a hermetically sealed electric motor unit connected to a pump unit is exposed at a suction passage communicating between a suction port provided in the apparatus main body and a suction unit of the pump unit, and the electric motor unit is A seal member is provided between the opposing frame ends and the outer peripheral portion of the tip of the output shaft, and a filter is provided at a portion outside the seal member between the frame member and the filter member.
The portion exposed to the outside of the filter is provided on the output shaft so as to cover the portion, and the inner surface has a seal portion that comes into contact with the exposed portion of the filter.
The submersible pump device according to claim 1, wherein vanes are provided on an outer peripheral surface of the invasion preventing color to generate a water flow to the surroundings as the output shaft rotates.