JPH10115295A - Canned motor pump - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suck/discharge safely without the generation of sudden boiling and form a small and simple structure with a small flow rate, high lift and no leak by having a canned motor, plural pumps with an impeller, a connection piping, a liquid introduction part and a liquid discharge port. SOLUTION: A rotary shaft 5 is projected from a canned motor 4 and extended. Plural impellers 9, 15 are installed on this rotary shaft 5 and plural pumps 10, 16 are installed. A liquid suction part 13 and discharge parts 14, 20 for discharging the liquid to the outside of the pump rooms 10, 16 by the high speed rotation of the impellers 9, 15 are provided in the pump rooms 10, 16. The pump room is formed so as to be released toward the discharge parts 14, 16 by the centrifugal force of the impeller. In the pump parts 2, 3, respective impellers 9, 15 are installed coaxially to the same rotary shaft 5. Plural pump parts 2, 3 are connected in series and the discharge pressure of a liquid is increased per the step number of the pump parts 2, 3. A liquid introduction part 22 and a liquid discharge part 23 for discharging the liquid in the canned motor part 4 into the pup parts 2, 3 adjacent to the canned motor part 4 are provided.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a canned motor pump, and more particularly to a canned motor pump capable of suctioning and discharging even a liquid having a high vapor pressure without causing bumping, thereby realizing a high head with a small flow rate. The present invention relates to a highly reliable canned motor pump having a simple structure.

[0002]

2. Description of the Related Art Conventionally, a canned motor pump capable of sucking and discharging a liquid having a high vapor pressure and not being a reverse type is disclosed in
There is a canned motor pump described in JP-A-158703 and JP-A-55-117650. In each of these canned motor pumps, a part of the discharge liquid is taken out from the discharge side of a pump chamber having a main impeller, and is discharged to an auxiliary pump chamber having an auxiliary impeller provided on a main shaft of a rotor to which the main impeller is attached. A part of the liquid is introduced, the pressure of the liquid is increased in the auxiliary pump chamber, and then the liquid is introduced into the canned pump chamber. The liquid introduced into the canned pump chamber cools the rotor of the canned motor. The liquid that has cooled the rotor section is returned to the pump chamber.

The auxiliary pump in such a canned motor acts to pressurize the liquid drawn from the pump chamber, and passes the liquid drawn from the pump chamber back to the pump chamber through the canned motor. It has a liquid circulation action and does not affect the pump action by the pump chamber.

[0004] In addition, although the auxiliary pump in this type of pump has much lower power than the main impeller even though the auxiliary pump increases the hydraulic pressure, the degree of pressure increase is small. Therefore, when a liquid having a high vapor pressure is suctioned and discharged by such a pump, the liquid having a high vapor pressure in the canned motor is heated by the heat generated in the canned motor, and is likely to be bumped. Therefore, there is a problem that such a canned motor pump cannot suck and discharge a liquid having a high vapor pressure without fear of bumping.

In particular, when a small flow rate and a high head are required, a reverse type pump is adopted instead of using the canned motor pump in multiple stages.

However, in a reverse type pump,
Since the reverse piping is required, the configuration of the apparatus becomes complicated, and the entire apparatus becomes large in size, so that downsizing cannot be achieved.

On the other hand, in recent years, from the viewpoint of environmental protection, CFC cannot be used as a refrigerant,
Various substances have been proposed as CFC substitutes. Many of the proposed alternatives to CFCs have high vapor pressure at normal pressure. In addition, CFC substitutes having a high vapor pressure have been used in various small-sized air conditioners from the viewpoint of energy saving. In this air conditioner, a pump having a small flow rate and a high head capability is required. In addition, a canned motor pump is often used because a pump incorporated in a cooling / heating device must almost completely prevent leakage of refrigerant. Therefore, a canned motor pump that can suction and discharge a liquid having a high vapor pressure, can achieve a high head with a small flow rate, and has no liquid leakage, and has a small and simple configuration is desired.

It is an object of the present invention to provide a canned motor pump capable of safely sucking and discharging a liquid having a high vapor pressure without causing bumping. An object of the present invention is to provide a canned motor pump having a small flow rate and a high head. SUMMARY OF THE INVENTION An object of the present invention is to provide a canned motor pump which is small in size, does not leak liquid, and has a simple structure.

[0009]

Means for solving the above problems are as follows. (1) A rotary shaft mounted with a rotor housed in a can so as to be separated from a stator is supported by a sliding bearing. A canned motor section, a plurality of pump sections each having an impeller mounted coaxially with the rotary shaft, and a discharge section of a front-stage pump section and a rear-stage pump section so as to increase the head of the last-stage pump section. A connection pipe for connecting the suction section, a liquid introduction section for introducing a part of the discharge section side of the pump section adjacent to the canned motor section into the canned motor section, and a liquid introduced into the canned motor section, And a liquid discharge section for discharging the liquid into a pump section adjacent to the introduction section and adjacent to the can motor section. (2) In the canned motor section, A first main impeller mounted on a rotating shaft having a motor, and a first suction part for sucking the liquid and a first discharge part for discharging the liquid by the first main impeller. A pump unit, a second main impeller mounted coaxially with the rotary shaft, and a second suction unit that sucks the liquid discharged from the first discharge unit through a connection pipe; A second pump section having a second discharge section for discharging, a liquid introduction section for introducing a liquid introduced into the second pump section into the canned motor section, and a first pump section or a second pump section inside the canned motor section. And (3) a liquid introduction section according to (2), wherein the liquid introduction section includes:
A liquid sending pipe for extracting a part of the liquid in the first discharge part of the first pump part and sending it to the second suction part of the second pump, and a liquid introduction for introducing a part of the liquid in the second pump part into the canned motor. 3. The canned motor according to (2), wherein the liquid discharging unit according to claim 2 has a liquid discharging hole for feeding the liquid in the canned motor unit into the first pump unit. pump.

(4) The liquid introducing section according to (2),
A liquid sending pipe for extracting a part of the liquid in the second discharge part of the second pump part and sending the liquid to the canned motor part is provided. The canned motor pump according to the above (2), which has a liquid discharge hole for feeding a liquid into the pump section, and (5)
The liquid supply pipe according to the above (3) or (4) is the canned motor pump according to the above (3) or (4), further including cooling means for cooling a liquid flowing through the inside thereof. (6) The first ejection section described in (2) and the second ejection section described in (2) are designed such that their ejection directions are opposite to each other. (7) The discharge amount of the second pump portion described in (2) is the discharge amount of the first pump portion and the introduction of liquid from the second pump portion to the canned motor portion. The canned motor pump according to the above (2), wherein the canned motor pump is set so as to be a total amount of the canned motor.

[0011]

DESCRIPTION OF THE PREFERRED EMBODIMENTS A canned motor pump according to the present invention has a stator, a rotor and a can, similarly to a normal canned motor pump. The can separates the stator from the rotor and houses the rotor inside the can. A stator is arranged outside the can to surround the rotor. The space inside the can and in which the rotor exists is called a canned motor section.

The rotor is mounted on a rotating shaft. By energizing the stator, the rotor rotates,
As a result, the rotation shaft also rotates. The rotating shaft is supported by sliding bearings provided on both sides of the rotor.
There is a slight gap between the sliding bearing and the rotating shaft.

The can incorporates the rotor. The canned motor section incorporating the rotor has a liquid introducing section, a liquid discharging section, and a gap between the sliding bearing and a rotating shaft, which will be described later, through which a liquid filled in the canned motor section can pass to the outside. Has a closed space without a hole communicating with the outside.

The rotating shaft projects from the canned motor portion,
Extend. A plurality of impellers are attached to a rotating shaft extending outside the canned motor unit. That is, a plurality of pump units are provided on the rotating shaft.

Each of the pump sections has an impeller mounted on a rotating shaft and a pump chamber for accommodating the impeller.
A liquid suction portion provided to introduce the liquid flowing in from the same direction as the rotating shaft, and a discharge portion for discharging the liquid to the outside of the pump chamber by high-speed rotation of the impeller, and from the liquid suction portion to the pump chamber. The introduced liquid is formed so as to be discharged toward the discharge portion by the centrifugal force of the impeller.

[0016] In the canned motor pump according to the present invention, the pump unit attached to the rotating shaft has at least two pump parts.
Group, and the number is not particularly limited. The number of pump sections can be determined according to the required head.

In the pump section of this canned motor pump, both impellers are coaxially mounted on the same rotating shaft. The impeller in each pump unit may be attached to one side or both sides of the canned motor unit.

In any case, each pump section is connected in series. In other words, the plurality of pump units attached to the rotating shaft are referred to as a first-stage pump unit and a second-stage pump unit. Yes, preferably 1 to 10, more preferably 1
It is a positive number of ~ 5. ), The first stage pump unit has its suction unit connected to a pipe or the like for sending the liquid to be sucked to the canned motor pump, and the discharge unit of the first stage pump unit is connected to the second stage pump unit. The suction port of the first-stage pump section is connected to the suction section of the first-stage pump section by a first connection pipe so that liquid is sent from the discharge section of the first-stage pump section to the suction section of the second-stage pump section. The discharge unit of the two-stage pump unit and the suction unit of the third stage are connected to each other so that the liquid is sent from the discharge unit of the second stage pump unit to the suction unit of the third stage pump unit. In the same manner, the discharge section of the k-th stage (where k is a positive number from 1 to n-2) and the suction section of the k + 1-th stage pump section are connected in the same manner. Are connected by a k-th connecting pipe so that the liquid is sent from the k-th discharge section to the suction section of the (k + 1) -th pump section, Is connected to the discharge section of the pump section in the stage immediately before the final stage by an (n-1) th connection pipe, and the discharge section of the pump section in the final stage sends the liquid to a predetermined section. I have.

As described above, since a plurality of pump units are connected in series such that a plurality of impellers are mounted coaxially on the rotating shaft, the discharge pressure of the liquid increases as the number of stages of the pump unit increases, and the pumping speed increases. The process is realized.

On the other hand, in the canned motor pump according to the present invention, a liquid introduction section for feeding a part of the liquid discharged from the discharge section of the pump section into the canned motor section, and a liquid in the canned motor section is supplied to the canned motor section. And a liquid discharge section for discharging the liquid into an adjacent pump section.

The liquid introduction section can take various forms as long as it has the above-mentioned function. For example, the liquid introduction section has a pump section on both sides of the canned motor section and the pump section is provided on one side of the canned motor section. It is possible to first consider the case where there is a pump section on the other side of the canned motor section.

In the case where there are pump sections on both sides of the canned motor section, the liquid introduction section is provided adjacent to one side of the canned motor section, or some pump sections are arranged adjacent to the pump motor section. A liquid supply pipe connecting the discharge section of the pump section other than the first stage and the suction section of the pump section provided adjacent to the other side of the canned motor section, and the other of the canned motor section And a liquid introduction hole communicating with the canned motor unit and the pump unit provided adjacent to the side. In this case, the discharge hole is formed on one side of the canned motor portion, and is formed by a pump portion having a discharge portion connected to the liquid supply pipe and a liquid discharge hole communicating with the inside of the canned motor portion. Can be.

Here, the liquid introduction hole and the liquid discharge hole may be through holes provided in the member, or may be pipes connecting the inside of the canned motor section and the inside of the pump section.

In the case where the pump section is provided only on one side of the canned motor section, the liquid introducing section is provided adjacent to one side of the canned motor section, or some liquid introducing sections are provided adjacent to the pump motor section. A part of the liquid discharged from the discharge unit of the pump unit other than the first stage provided via the pump unit may be formed by a liquid sending pipe for introducing the liquid into the canned motor unit from the other side of the canned motor unit. it can. In this case, the liquid discharge hole is formed on one side of the canned motor unit, and is formed by a pump unit having a discharge unit connected to the liquid supply pipe and a liquid discharge hole communicating with the inside of the canned motor unit. be able to. Here, the liquid introduction hole and the liquid discharge hole are
It may be a through hole provided in the member, or a pipe connecting the inside of the canned motor section and the inside of the pump section.

In the canned motor pump having such a structure, the pressure of the liquid passing through the canned motor section is increased by pushing a part of the liquid discharged from the pump section into the canned motor section. Since the pressure of the liquid increases in the canned motor section, even when the boiling point of the liquid is low, bumping of the liquid in the canned motor section is prevented by the heat generated by the stator.

Further, it is preferable to provide a cooling means for cooling the liquid flowing through the liquid sending pipe.

The outline of the canned motor pump having a plurality of pump portions has been described above. Hereinafter, a preferred canned motor pump having two pump portions will be specifically described.

(Embodiment 1) FIG. 1 is a schematic explanatory view showing a canned motor pump according to an embodiment of the present invention.

As shown in FIG. 1, the canned motor pump 1 includes a first pump section 2, a second pump section 3, and a canned motor section 4.

The canned motor section 4 includes a rotor 6 provided on a rotating shaft 5, a can 7 surrounding the rotating shaft 5 and the rotor 6, and a rotor 6 provided outside the can 7.
And a stator 8 arranged so as to surround the The stator 8 is a coil, and the rotor 6 is rotated by energizing the stator 8.

The can 7 separates the rotor 6 from the stator 8 and circulates the liquid inside the can 7, that is, the internal space accommodating the rotor 6. A function of cooling the heating caused by energizing the motor and a function of lubricating the rotation of the rotating shaft 5 are provided. In this embodiment, the liquid is referred to as a handling liquid.

First ends are provided at both ends of the canned motor section 4 respectively.
A pump section 2 and a second pump section 3 are provided.

The first pump section 2 has a first impeller 9 and a first pump section case 11 that forms a first pump chamber 10 that houses the first impeller 9.

The first pump section 2 is adjacent to the canned motor section 4, and the first pump section case 11 closes one end opening of the can 7 in the canned motor section 4. The rotary shaft 5 extends so as to penetrate into the first pump chamber 10, and the first impeller 9 is mounted on the rotary shaft 5 in the first pump chamber 10. In order to allow the rotating shaft 5 to penetrate into the first pump chamber 10, an insertion hole 12 is provided in a wall separating the internal space of the can 7 and the first pump chamber 10, and a sliding bearing 12 </ b> A is formed in the insertion hole 12. Is attached. The rotating shaft 5 is inserted through the sliding bearing 12A. The inner diameter of the sliding bearing 12A is designed to be larger than the diameter of the rotating shaft 5, and the liquid inside the can 7 passes through the gap between the inner periphery of the sliding bearing 12A and the outer periphery of the rotating shaft 5 so that the liquid in the first pump chamber 10 It can be distributed to The liquid flowing through the sliding bearing 12A is:
The lubricating liquid acts when the rotating shaft 5 rotates.

The first pump chamber 10 houses the first impeller 9 inside. The first impeller 9 discharges the liquid introduced from the first suction part 13 to the outside of the first pump chamber 10 through the first discharge part 14 by using the centrifugal force generated by the high speed rotation of the first impeller 9. It is formed to perform a function.

As the form of the first impeller 9, an impeller employed in a normal canned motor pump 1 can be employed.

As a more specific form of the first impeller,
For example, a rotating table pivotally supported by a rotating shaft, and a rotating blade or a rotating blade that stands radially on a surface of the rotating table facing a liquid to be introduced from a direction parallel to the rotating shaft, The impeller formed so that the rotating blade or the rotating blade is rotated at a high speed by the high-speed rotation of the rotating shaft and the handling liquid is discharged from the first discharging portion by centrifugal force can be raised. A disc-shaped body, and an inflow pierced hole having a circular opening formed in a plane of the disc-shaped body facing the liquid introduced from a direction parallel to the rotation axis; It has an internal opening on the inner peripheral surface and has an external opening on the outer peripheral surface of the disk-shaped body, and is arranged radially from the center of the disk-shaped body, from the internal opening to the external opening. And a through hole penetrating therethrough,
The rotation of the rotating shaft causes the disk-shaped body to rotate at a high speed, and the high-speed rotation of the disk-shaped body forms an impeller or the like formed to discharge the handling liquid flowing into the inflow immersion hole of the disk-shaped body through the through-hole. I can give it.

The first suction part 13 is formed so as to introduce the handling liquid into the first pump chamber 10 from a direction along the axis of the rotating shaft 5. Although not shown in FIG. 1, a diffuser may be attached to the first suction section 13.

The first discharge unit 14 causes the handling liquid to flow by the centrifugal force of the rotation shaft 5 by the high-speed rotation of the first impeller 9.
Is formed so as to be emitted in the radial direction. Therefore, the first discharge unit 14 is provided in a direction orthogonal to the rotation shaft 5.

The second pump section 3 includes a second impeller 15
And a second pump section case 17 that forms a second pump chamber 16 that accommodates this.

The second pump section 3 is provided at the end of the canned motor section 4 opposite to the side where the first pump section 2 is provided, and the other end of the can 7 in the canned motor section 4 is provided. The second pump unit case 17 closes the opening.

The rotating shaft 5 disposed in the can 7
Extends so as to penetrate into the second pump chamber 16,
In the pump chamber 16, the second impeller 15 is
Is installed. To penetrate the rotary shaft 5 into the second pump chamber 16, an insertion hole 18 is provided in a wall separating the internal space of the can 7 and the second pump chamber 16. The slide bearing 12B is mounted in the insertion hole 18. The rotating shaft 5 is inserted through the sliding bearing 12B. The inner diameter of the slide bearing 12B is designed to be larger than the diameter of the rotary shaft 5, and the liquid inside the can 7 passes through the gap between the inner circumference of the slide bearing 12B and the outer circumference of the rotary shaft 5, and the second pump chamber. 16 can be distributed. The liquid flowing through the insertion hole 18 acts as a lubricating liquid when the rotating shaft 5 rotates.

The second pump chamber 16 houses the second impeller 15 inside. The second impeller 15 has a second suction portion 19.
The liquid introduced from the second impeller 15 is handled by centrifugal force generated by the high speed rotation of the second impeller 15 and the liquid is handled by the second discharge unit 20.
It is formed so as to have a function of discharging the liquid to the outside of the second pump chamber 16 through the second pump chamber 16.

As the form of the second impeller 15, an impeller employed in a normal canned motor pump 1 can be employed. In this embodiment, the second impeller 15 is connected to the end of the rotary shaft 5 so as to be opposite to the first impeller 9 with respect to the rotary shaft 5, except for the first impeller 9. It has the same structure as one impeller 9.

The second suction part 19 is formed so as to introduce the handling liquid into the second pump chamber 16 from a direction along the axis of the rotating shaft 5.

A pipe 21 connected to the first discharge section 14 is connected to the second suction section 19, and the handling liquid discharged from the first discharge section 14 is supplied to the second pump section through the second suction section 19. It is adapted to be introduced into the chamber 16.

The second discharge unit 20 is provided with the second impeller 15
Is formed so that the handling liquid is discharged radially with respect to the rotating shaft 5 by the centrifugal force due to the high-speed rotation of.
Therefore, the second discharge unit 20 is provided in a direction orthogonal to the rotation shaft 5. The second discharge unit 20 is provided with a discharge pipe.
The opening direction of the second discharge unit 20 is preferably opposite to the opening direction of the second ejection unit 20, that is, the opening direction of the second ejection unit 20 is preferably 180 °. When the angle between the opening direction of the first discharge unit 14 and the opening direction of the second discharge unit 20 is set to 180 °, the first discharge unit 14 is rotated by the high-speed rotation of the first impeller 9.
Of the handling liquid discharged from the second impeller 15 and the high-speed rotation of the second impeller 15 balance the force of the handling liquid discharged from the second discharge unit 20, and the vibration is reduced when the canned motor pump 1 is operated. It is.

The second pump chamber 16 is provided with a liquid introduction section 22 for introducing the handling liquid introduced into the second pump chamber 16 into the canned motor section 4. In other words, the liquid introduction part 22 is formed so that the handling liquid in the second pump chamber 16 can be introduced into the can 7. The liquid introduction section 22 is appropriately designed to have the above-described function, but as a preferred embodiment, the second pump chamber 16
The rotation of the second impeller 15 at
A liquid introduction hole 22A formed so as to introduce the pressurized liquid flow toward the discharge section 20 and into the canned motor section 4, more precisely, into the can 7, can be mentioned. FIG.
In the second embodiment, the liquid inlet having an opening in the second pump chamber 16 immediately before the second discharge unit 20 and outside the rotation range of the second impeller 15 and communicating with the canned motor unit 4 is provided. A hole 22A is provided. The handling liquid pressurized in the second pump chamber 16 by the high-speed rotation of the second impeller 15 is supplied to a sliding bearing 12B provided on a wall separating the internal space of the can and the second pump chamber 16 from each other.
If it is possible to enter the canned motor section 4 through the gap between the sliding bearing 12B and the rotating shaft 5 inserted into the sliding bearing 12B, the gap between the sliding bearing 12B and the rotating shaft 5 is also reduced to the liquid introducing section. 22. However,
Since the gap between the sliding bearing 12B and the rotary shaft 5 is extremely small, the liquid introduction unit 22 for reliably feeding the handling liquid pressurized in the second pump chamber 16 into the canned motor unit includes the second pump chamber 16 , The second ejection unit 20
It is preferable that the liquid inlet 22A has an opening at a position just outside of the rotation range of the second impeller 15 and communicates with the canned motor section 4.

The first pump chamber 10 is provided with a liquid discharge section 23 for discharging the handling liquid press-fitted into the canned motor section 4 from the canned motor section 4 into the first pump chamber 10. In this embodiment, the liquid discharging section 2
Reference numeral 3 denotes a partition wall that separates the canned motor unit 4 from the first pump chamber 10, an opening that opens on the side of the canned motor unit 4, and an opening that opens at a position off the first impeller 9 in the first pump chamber 10. Is provided with a liquid discharge hole 23A which communicates with the liquid.

In the second pump section, the pumping capacity is such that the discharge amount of the second pump section from the second discharge section flows into the canned motor section from the discharge amount of the first pump section and the second pump section. Preferably, it is designed to be the sum with the inflow.

The operation of the canned motor pump 1 having the above configuration is as follows.

When the stator 8 is energized, the rotor 6
To rotate at high speed. The high speed rotation of the rotor 6 causes the rotation shaft 5
When the motor rotates at a high speed, the first impeller 9 also rotates at a high speed. From the first suction part, the handling liquid is introduced into the first pump chamber 10 from a direction parallel to the rotating shaft 5. The introduced handling liquid is subjected to the first rotation by the centrifugal force of the high-speed first impeller 9.
It is discharged from the discharge unit 14. At this time, as shown in FIG. 2, assuming that the pressure of the handling liquid in the first suction section is P ₀ , the pressure of the handling liquid pressurized by the centrifugal force due to the high-speed rotation of the first impeller 9 becomes the first discharge pressure. It becomes P _{1 in the} unit 14. The pressure of the handling liquid flowing through the pipe 21 from the first discharge part 14 to the second suction part slightly decreases, and the pressure of the handling liquid becomes P ₂ in the second suction part. In the second pump chamber 16, the handling liquid is discharged from the second discharge unit 20 by the centrifugal force of the second impeller 15 rotating at high speed. At this time, handling solution by the action of the second impeller 15 increases the pressure P _3. Some of handling liquid of the increased pressure P ₃ is through the liquid introducing hole 22A, is introduced into the canned motor unit 4. The pressure of the introduced handling liquid canned motor unit 4 is reduced slightly P _4. And
The handling liquid is supplied to the rotating shaft 5 in the canned motor unit 4.
And flow along the rotor 6, reducing between the pressure P _5. This handling liquid introduced into the canned motor unit 4 is raised to P _3, canned motor unit 4
Even if it is said that the pressure is reduced within
₅ is a pressure higher than P _1.

On the other hand, as shown by the crosses in FIG. 2, the vapor pressure of the liquid to be handled is from the first suction part 13 to the first discharge part 14, the pipe 21, the second suction part 19, and the liquid introduction hole 22A.
Until the heat is introduced into the canned motor section 4 through the through hole, no particular heating is performed, so that the vapor pressure is substantially constant. When passing through the inside of the canned motor section 4, the handling liquid is heated by the heat generated by the stator 8, and the vapor pressure is increased.

However, the handling liquid whose pressure has been increased in the second pump chamber 16 is introduced into the canned motor section 4 at that pressure, so that the handled liquid in the canned motor section 4 has a higher vapor pressure than that of the canned motor section. Is also at high pressure. In other words, only the difference between the pressure P ₅ and handling liquid vapor pressure, does not occur bumping by heating in from the pressure of the pumped fluid is high, even within the canned motor unit 4 even at low boiling points handling liquid.

In this embodiment, since the first pump section 2 and the second pump section 3 are designed to be used substantially in the same manner, two pumps sharing one rotary shaft 5 are driven by the canned motor. It is the same as being done. In other words, the main pump and the auxiliary pump driven by one rotary shaft 5 are not provided, but two main pumps are driven at the same time.

In the canned motor pump 1 of this embodiment, the current supplied to the stator 8 may be controlled by an inverter. When the drive of the motor is controlled by the inverter, the rotation speed of the rotating shaft 5 can be controlled, and low-speed rotation and high-speed rotation can be freely performed.

(Example 2) In this example, a low-boiling-point handling liquid having a high vapor pressure was produced without bumping.
A canned motor pump that performs suction and discharge is exemplified.

The canned motor pump of this embodiment is substantially the same as the canned motor pump of the first embodiment except that the pipe 21 is provided with a cooling means. It is.

Examples of the cooling means include an air-cooled cooling means and a refrigerant-cooled cooling means using a refrigerant. Examples of the air-cooling type cooling unit include a cooling unit in which a large number of fins are also arranged on the outer periphery of the pipe. Further, as the refrigerant cooling type cooling means, a cooling means in which a jacket through which a refrigerant such as water can flow is provided on the outer periphery of the pipe, or a cooling pipe through which the refrigerant such as water flows in the pipe is provided. Cooling means.

When a cooling means is provided in a pipe connecting the first discharge section to the second suction port, as shown by an X in FIG. 3, the handling liquid flowing through the pipe is cooled,
By the time the liquid flows into the pump chamber, the vapor pressure of the handling liquid decreases, and a part of the handling liquid is introduced into the canned motor with the reduced vapor pressure. The handling liquid whose vapor pressure has been lowered by the cooling means, even if heated in the canned motor section, is slight, and returns to the temperature of the handling liquid in the first pump section near the liquid discharge section.

Therefore, by providing a cooling means in the pipe, the vapor pressure of the handling liquid flowing through the canned motor section is reduced, and the discharge liquid from the first pump section is introduced into the second pump section to reduce the pressure of the discharge liquid. Since the pressure is very high, the pressure difference leading to bumping of the handling liquid flowing in the canned motor portion becomes large, and the possibility of bumping becomes extremely low.

(Embodiment 3) FIG. 4 shows another embodiment of the present invention. FIG. 4 is a schematic explanatory view showing a canned motor pump according to another embodiment of the present invention. FIG. 4 shows in principle a canned motor pump according to another embodiment.

As shown in FIG. 4, this canned motor pump 31 is outside a can (not shown) having a rotor 32 supported on a rotating shaft and corresponds to the rotor 32, and It has a stator (not shown) arranged so as to surround the rotor 32. In the canned motor pump 31, one end of the can is closed by an appropriate member (not shown), and one end of the rotating shaft 32 is inserted into a support hole 34A through which the rotating shaft 33 is inserted. The other end of the can, that is, the end opposite to the one end of the can is closed by a suitable member, and the proper member is provided with a support hole 34B through which the rotating shaft 33 is inserted. Is inserted through the rotating shaft 33.

The inner diameter of the pair of support holes 34A and 34B through which both ends of the rotary shaft 33 are inserted is designed to be larger than the outer shape of the rotary shaft 33.
The liquid can flow through the gap between the inner circumference of A and 34B.

The other end of the rotating shaft 33 is further extended and penetrates a second pump section (not shown), and a first pump section (not shown) provided adjacent to the second pump section. ) In the first pump chamber (not shown).

The first pump section is provided in the first pump chamber, the first impeller 35 housed in the first pump chamber and supported by the rotating shaft 33, and provided in the first pump chamber, A first suction part (not shown) that opens in the axial direction of the shaft 33 and a centrifugal force generated by the high-speed rotation of the first impeller 35 by using the handling liquid introduced into the first pump chamber from the first suction part. And a first discharge unit (not shown) that discharges in a radial direction with respect to the rotation shaft 33.

The second pump section is interposed between the can and the first pump section. The second pump section includes a second pump chamber and the rotary shaft 3 housed in the second pump chamber.
3 and a second impeller 36 supported by the second impeller 36. This second
The impeller 36 is mounted on the rotating shaft 33 in a direction opposite to the first impeller 35. The second pump section is a second suction section (not shown) which is in the axial direction of the rotary shaft 33 and opens to the can side, and a second pump section for handling liquid introduced into the second pump chamber from the second suction section. A second discharge portion (not shown) that discharges radially with respect to the rotation shaft 33 with the centrifugal force due to the high-speed rotation of the second impeller 36.

The first discharge part and the second suction part are connected to the flow path 3
7 For example, they are connected by a flow pipe or a flow pipe. Therefore, from the second discharge unit, the handling liquid further increased by the second impeller 36 and the handling liquid increased by the first impeller 35 is ejected at a higher pressure. In other words, since the first pump unit and the second pump unit are connected in series, a high head output is achieved. Achieving a high head by connecting the first pump section and the second pump section in series is a technical effect commonly seen in the canned motor pump of the present invention.

The second discharge section is in the opposite direction to the discharge direction of the first discharge section, ie, at an angle of 180 °, as in the canned motor pump 31 shown in FIG.
It is preferably provided in a pump chamber. Since the first discharge portion and the second discharge portion are oriented in opposite directions, noise or vibration during operation of the canned motor pump 31 can be suppressed to a small value.

A branch pipe 39, which is a branch pipe, is attached to the discharge main pipe 38 attached to the second discharge section. The branch pipe 39 is provided at the closed end of the can, and the rotating shaft 3
3 is connected to the introduction space toward the support hole 34A that supports the support hole 3A.

The gap formed between the inner peripheral surface of the support hole 34A communicating with the introduction space and the outer peripheral surface of the support member among the support holes 34A provided in an appropriate member for closing the can at both ends of the can. Then, the handling liquid is introduced from the introduction space into the canned motor portion through this gap.

In this embodiment, the branch pipe 39, the introduction space toward the support hole 34A for supporting the rotary shaft 33, and the inner peripheral surface of the support hole 34A and the rotary shaft 33 communicating with the introduction space. The liquid introduction part in the present invention is formed by the gap with the outer periphery.

A support hole 34B provided in the other appropriate member closing the other opening of the can communicates with the second pump chamber. Therefore, the gap formed between the inner peripheral surface of the support hole 34B communicating with the second pump chamber and the outer peripheral surface of the rotary shaft 33 discharges the liquid handled in the canned motor section to the second pump chamber. Is a liquid discharge section.

As described above, the gap formed between the inner peripheral surface of the support hole 34A through which the rotary shaft 33 is inserted and the outer peripheral surface of the rotary shaft 33 is defined as a part of the liquid introduction part and the liquid discharge part. This is convenient when the amount of liquid handled by the canned motor pump 31 is small. If the amount of liquid handled by the canned motor pump 31 increases, in addition to the gap formed between the inner peripheral surface of the support hole 34A of the rotating shaft 33 and the outer peripheral surface of the rotating shaft 33, a sufficient flow rate It is particularly preferable to provide a flow passage through which the handling liquid can flow.

The canned motor pump 31 shown in FIG.
In FIG. 5, as shown in FIG. 5, when the pressure of the handling liquid at the first suction port is P ₀ , the pressure of the handling liquid pressurized by the first impeller 35 at the first discharge unit becomes P ₁ . Up to Handling solution elevated to P ₁ is, in the vicinity of the second suction unit decreases slightly P _2. The handling liquid flowing into the second pump chamber from the second suction part is
Is further pressurized by the second impeller 36 is discharged from the second discharge portion is increased to P _3. A part of the handling liquid discharged from the second discharge part reaches the introduction space provided in an appropriate member for closing the end of the can through the branch pipe, and is discharged through the gap between the support hole 34A and the rotating shaft 33. It flows into the motor section. At this time, handling liquid led to the introduction space will P ₄ slightly reduced pressure. Then, within the canned motor unit, subtracts handling liquid addition, P _4, and the rotary shaft 3 and the support hole 34B communicating with the second pump
Just before reaching the gap between the 3 decreases to P _5. However, handling liquid fed into the canned motor unit, since the increased to a sufficiently high P _3, the pressure of P ₅ is higher than P _2.

On the other hand, since the handling liquid is not particularly heated in the first suction section, the first discharge section, the second suction section, the second discharge section and the introduction space, the vapor pressure is substantially constant.
In the canned motor section, the handling liquid is heated by heat generated by energization of the stator, and increases its vapor pressure. However, since increased vapor pressure pressure of the pumped fluid is sufficiently high as P _5, does not lead to its handling liquid causes a bumping even at a low boiling point fluid.

(Embodiment 4) This embodiment is similar to the embodiment 4 described above.
The present invention relates to a canned motor pump in which cooling means is provided in a branch pipe 39 of the canned motor pump shown in FIG.

The cooling means is the same as that described in the second embodiment.

The technical effect of providing the cooling means is the same as that described in the second embodiment. In addition,
FIG. 6 shows the relationship between the pressure of each part of the canned motor pump of the handling liquid and the vapor pressure. The meaning of FIG. 6 is substantially the same as the meaning of FIG.

[0080]

According to the present invention, a liquid having a high vapor pressure is
A canned motor pump capable of safely sucking and discharging without bumping can be provided. According to the present invention, it is possible to provide a canned motor pump having a small flow rate and a high head. According to the present invention, it is possible to provide a small-sized canned motor pump which does not leak liquid and has a simple structure.

[Brief description of the drawings]

FIG. 1 is a schematic explanatory view showing one embodiment of the present invention.

FIG. 2 is a graph showing a relationship between a pressure of a handling liquid and a vapor pressure in each part of the canned motor pump shown in FIG.

FIG. 3 is a diagram showing pressure and vapor of a liquid handled in each part of the canned motor pump when a cooling means is provided in a pipe from a first discharge part to a second suction part in the canned motor pump shown in FIG. 1; It is a graph which shows the relationship with pressure.

FIG. 4 is a schematic explanatory view showing another embodiment of the present invention.

FIG. 5 is a graph showing a relationship between a pressure of a handling liquid and a vapor pressure in each part of the canned motor pump shown in FIG.

FIG. 6 is a graph showing a relationship between a pressure of a handling liquid and a vapor pressure in each part of the canned motor pump when a cooling means is provided in a branch pipe in the canned motor pump shown in FIG.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Canned motor pump, 2 ... 1st pump part, 3 ... 2nd pump part, 4 ... Canned motor part, 5 ... Rotating shaft, 6 ... Rotor, 7 ...・ Can, 8 ・ ・ ・ Stator, 9 ・ ・ ・ First impeller, 10 ・
..First pump chamber, 11 ... first pump section case, 1
2 ... insertion hole, 12A, 12B ... sliding bearing, 1
3 ... first suction unit, 14 ... first discharge unit, 15 ...
-2nd impeller, 16 ... 2nd pump room, 17 ...
2nd pump part case, 18 ... insertion hole, 19 ... second suction part, 20 ... second discharge part, 21 ... piping, 2
2 ... liquid introduction part, 22A ... liquid introduction hole, 23 ...
Liquid discharge part, 23A ... liquid discharge hole, 31 ... canned motor pump, 32 ... rotor, 33 ... rotating shaft,
34A ... support hole, 34B ... support hole, 35 ...
1st impeller, 36 ... 2nd impeller, 37 ... Flow path, 38 ... 2nd discharge main pipe, 39 ... Branch pipe.

Claims (7)

[Claims] 1. A plurality of can motors each having a canned motor section having a rotating shaft mounted with a rotor housed in a can so as to be separated from a stator and supported by a sliding bearing, and impellers mounted coaxially with the rotating shaft, respectively. A pump section, a connecting pipe connecting the discharge section of the preceding pump section and the suction section of the subsequent pump section, and a pump section adjacent to the canned motor section so as to increase the head of the final stage pump section. A liquid introduction part for introducing a part of the discharge part side into the canned motor part,
A can discharge means for discharging a liquid introduced into the canned motor section into a pump section adjacent to the canned motor section on a side opposite to the liquid introducing section. 2. A canned motor having a first main impeller mounted on a rotating shaft having a rotor in a canned motor section, a first suction section for sucking a liquid, and a first suction section for discharging a liquid by the first main impeller. A second pump having a first pump section having a discharge section, and a second main impeller mounted coaxially with the rotary shaft, wherein the second pump section sucks liquid discharged from the first discharge section through a connection pipe. A second pump unit including a suction unit and a second discharge unit that discharges the sucked liquid, a liquid introduction unit that introduces the liquid introduced into the second pump unit into the canned motor unit,
A liquid discharge section for discharging liquid from inside the canned motor section into the first pump section or the second pump section. 3. The liquid introduction part according to claim 2, wherein
A liquid sending pipe for extracting a part of the liquid in the first discharge part of the pump part and sending it to the second suction part of the second pump, a liquid introduction hole for introducing a part of the liquid in the second pump part into the canned motor; 3. The canned motor pump according to claim 2, wherein the liquid discharging section according to claim 2 has a liquid discharging hole for feeding the liquid in the canned motor section into the first pump section. 4. 4. The liquid introducing section according to claim 2, wherein
3. The liquid discharge pipe according to claim 2, further comprising a liquid feed pipe for extracting a part of the liquid from the second discharge part of the pump part and sending the liquid to the can motor part. 3. The canned motor pump according to claim 2, wherein the canned motor pump has a liquid discharge hole for sending the liquid to the pump. 5. The liquid supply pipe according to claim 3 or claim 4, wherein the liquid supply pipe according to claim 3 or 4 has cooling means for cooling the liquid flowing through the liquid supply pipe. Canned motor pump. 6. The first discharge unit according to claim 2 and the second discharge unit according to claim 2 are designed such that their discharge directions are opposite to each other. Item 3. A canned motor pump according to Item 2. 7. The discharge amount of the second pump section according to claim 2 is a sum of the discharge amount of the first pump section and the liquid introduction amount from the second pump section to the canned motor section. The canned motor pump according to claim 2, which is set.