JP3490059B2 - Magnet pump - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention makes it possible to reduce the size of a pump housing without degrading the pump performance, and thus to increase the degree of freedom in installing or mounting the pump in a limited space, and to reduce the housing body Shared,
The present invention relates to a magnet pump capable of easily changing the partition wall body to various ones.

[0002]

2. Description of the Related Art In a conventional magnet pump housing, an opening of a pump chamber is provided in a perfect circle, and an impeller having an inner magnet is rotatably mounted in the pump chamber. The mounting portion of the partition wall is inserted into the circular opening of the pump chamber via a sealing material such as an O (O) ring, and the housing body and the partition wall are joined in a watertight manner. An outer magnet that rotates is disposed outside the partition body, and as the outer magnet rotates,
The impeller mounted in the pump chamber rotates. In such a magnet pump, a eddy-shaped wall is formed to extend toward the pump chamber at the end of the housing body of the mounting portion of the partition wall body.
No. 88.

[0003]

Generally, a pump housing in a magnet pump is composed of a housing main body and a partition body. On the partition body side, a groove is formed so that an O-ring can be fitted to the outer periphery of its mounting portion. Is formed, and a sealing material such as the O-ring is fitted into the groove to form a seal portion. Then, a vortex wall extends from the mounting portion of the partition wall toward the pump chamber side of the housing body to form a vortex chamber inside the pump chamber.

With such a structure, the vortex-shaped wall of the pump chamber and the mounting portion of the partition wall have a longer distance in the axial direction, so that the corresponding portion of the housing also becomes longer in the axial direction, and the pump main body becomes longer. Tends to grow in the axial direction. Thus, in the case of a pump in which the pump housing has to be elongated in the axial direction, it is extremely difficult to arrange the pump in a limited space. For example, when arranging a pump in an engine or the like, a high-performance pump is required in a limited space.

Therefore, it is necessary not only to simply downsize the pump but also to ensure high pump performance. However, miniaturization of the pump and maintenance of performance (reduction of deterioration) are contradictory conditions, and there is a difficult problem that both of them must be satisfied. An object of the present invention is to satisfy both of the above contradictory conditions.

[0006]

Therefore, as a result of earnest studies by the inventor in order to solve the above-mentioned problems, the present invention was found to be an impeller chamber including a perfectly circular inner peripheral wall surface and side surface portions. , A spiral wall surface formed in a range of about half of an inner peripheral wall surface of the impeller chamber so as to descend in a stepwise manner toward the inner side of the impeller chamber, and a spiral arc surface continuous with the spiral wall surface On the inner side, a housing body having riser wall portions formed on the outer peripheral side, each having a true arc-shaped surface spaced apart from the inner peripheral wall surface and having the same core as the inner peripheral wall surface, and a watertight seal on the inner peripheral wall surface. By using a magnet pump consisting of a partition wall with a true-cylindrical connection part to be inserted into the pump, the pump housing can be miniaturized without degrading the pump performance, and thus the pump can be installed or installed in a limited space. Degree of freedom Can be enlarged, also share the housing body, can the partition wall body easily be changed to various ones is obtained by solving the above problems.

[0007]

DETAILED DESCRIPTION OF THE INVENTION Embodiments of the present invention will be described below with reference to the drawings. The pump housing is composed of a housing body A and a partition body B, and the housing body A has an impeller chamber A ₁ formed therein. The impeller room A
_A circular inner wall surface 1 is formed in the opening ₁ . A side surface portion 2 is formed so as to be surrounded by the inner peripheral wall surface 1. An impeller 13, which will be described later, is rotatably mounted in the impeller chamber A ₁ .

A spiral wall surface 3 is formed so as to descend stepwise from the corner between the inner peripheral wall surface 1 and the side surface portion 2 toward the inner side of the impeller chamber A ₁ . The spiral wall surface 3 is formed in a range of about half of the inner wall surface 1 of the impeller chamber A ₁ . Further, a rising wall portion 4 is formed from the side surface portion 2 (see FIG. 3).

The rising wall portion 4 is formed so as to project from the side surface portion 2 and has a substantially half-moon shape. The inner peripheral side of the rising wall portion 4 is a spiral wall surface 3. And a spiral arcuate surface 4a having continuous spirals are formed. On the outer peripheral side of the rising wall portion 4, a true arcuate surface 4b having the same core as the inner peripheral wall surface 1 is formed. An insertion space s is formed at a predetermined distance from (see FIG. 1, FIG. 2, etc.). In the insertion space s,
The connecting portion 11 of the partition wall B described later can be inserted [see FIG. 2 (A), FIG. 6 and the like].

An impeller 13 is provided at the center of the side surface portion 2.
The impeller shaft 8 for mounting is mounted. A suction port is formed around the impeller shaft 8, and a suction port 6 is formed in the suction port. Further, an inclined concave portion 5 is formed in the side surface portion 2. The inclined recessed portion 5 is formed in an inclined shape so as to become gradually deeper along the flow direction of the fluid flowing in the impeller chamber A ₁ [FIG. 2 (B), FIG. 5 (A), (B)]. Etc.]. A discharge port 7 is formed at a peripheral end portion of the inclined concave portion 5.

Next, the partition wall B is made up of a storage portion 10 and a connecting portion 1.
1 and 1. The connection portion 11 is a portion to be inserted into the inner peripheral wall surface 1 of the housing body A, and the storage portion 10 is a portion in which an impeller 13 described later is stored [FIG. 1 (A), (B )reference〕. Further, in a state where the housing body A and the partition wall body B are joined, the center of the inner peripheral wall surface 1 at the opening of the impeller chamber A ₁ of the housing body A and the perfect circular connecting portion 11 of the partition wall body B.
It is coaxial with the center of each.

A groove 11a is formed on the outer peripheral side of the connecting portion 11 of the partition wall B, and the seal member 1 is formed in the groove 11a.
2 is fitted. The general seal member 12 uses a circular packing, for example, an O-ring. As described above, the connecting portion 11 of the partition wall B and the inner peripheral wall surface 1 of the housing body A both have a perfect circular structure, so that the sealability can be easily improved without using a special packing or the like. be able to.

Next, the impeller 13 is composed of an inner magnet portion 13a and an impeller portion 13b,
A bearing through hole 13c is formed at the center in the radial direction, and the bearing through hole 13c is rotatably supported by the impeller shaft 8.
The inner magnet part 13a is mounted in the impeller chamber A ₁ and is housed in the housing part 10 of the partition wall B [FIG.
(A), see FIG. 6]. The inner magnet portion 13a rotates with the rotation of an outer magnet (not shown) provided outside the partition wall B, whereby the impeller 13 rotates.

A connecting portion 11 is formed in a perfect circular shape on the side of the partition wall B, and a spiral wall surface 3 is formed in the opening of the impeller chamber A ₁ in which spirals are continuous with the spiral arc surface 4a of the rising wall portion 4. With this structure, it is not necessary to newly form a spiral portion on the side of the partition B, and the size of the partition B is changed according to the size of the impeller 13 with respect to the housing body A. Since it is also possible to make the housing main body A common, and it is possible to easily expand the variation of the partition body B.

As described above, the inclined concave portion 5 is formed so as to be gradually deepened toward the discharge port 7 of the side surface portion 2, but the inclined concave portion 5 will be more specifically described. To explain, the spiral arc surface 4a of the rising wall portion 4 is described.
And spiral surface 3 formed so that the spiral surface is continuous
The side surface portion 2 in the vicinity of the discharge port 7 is formed so as to be gradually deeper along the flow direction of the fluid [see FIGS. 5 (A) and 5 (B)].

Further, the spiral wall surface 3 may be formed so as to become deeper in the depth direction along the flow of the fluid from the end portion in the flow direction of the spiral arc surface 4a of the rising wall portion 4. At this time, the radial size of the spiral wall surface 3 can be set appropriately. As described above, since the spiral shape of the spiral wall surface 3 in the radial direction of the impeller is formed in the housing body A by changing the depth direction of the side surface portion 2 in the impeller chamber A ₁ of the housing body A, the partition wall body B is formed. The structure does not need to be provided with a spiral on the side.

[0017]

According to the first aspect of the present invention, the impeller chamber A ₁ is formed of the inner peripheral wall surface 1 and the side surface portion 2 having a perfect circular shape, and the stepped shape is lowered toward the inner side of the impeller chamber A _1. In this way, the spiral wall surface 3 formed in a range of about half of the inner wall surface 1 of the impeller chamber A ₁ and the spiral arc surface 4a continuous with the spiral wall surface 3 are directed to the inner side. A housing main body A having rising wall portions 4 formed on the outer peripheral side, which are separated from the wall surface 1 and have the same arcuate surface 4b as the same core as the inner peripheral wall surface 1, is inserted into the inner peripheral wall surface 1 in a watertight manner. Since the magnet pump is composed of the partition wall B on which the true-cylindrical connecting portion 11 is formed, the pump housing can be downsized without degrading the pump performance, and thus the pump can be installed in a limited space. Greater freedom of installation or mounting Rukoto can also share the housing body A, the effect of such a partition wall body B can be easily changed to vary.

The above effect is that since the inner peripheral wall surface 1, the side surface portion 2, the spiral wall surface 3 and the rising wall portion 4 are formed on the housing body A side, the spiral inner peripheral wall is formed on the partition wall B side. You don't have to. Furthermore, the inner peripheral wall surface _{1 at} the opening of the impeller chamber A ₁ of the housing body A and the connecting portion 11 of the partition wall B are formed into a perfect circular shape, and a vortex wall overlaps the opening. There is. As a result, it has become possible to reduce the size of the pump while ensuring pump performance without increasing the size of the pump in the axial direction.

Further, this can increase the degree of freedom in installing or installing the pump in the limited space. Further, since the housing main body A is shared and it is possible to easily change the partition body B corresponding to the shape and size of the impeller 13 to be mounted, the variation of the pump can be easily expanded. it can.

Next, in the invention of claim 2, in claim 1, an inclined concave portion 5 is formed in the side surface portion 2 near the formation of the discharge port 7 so as to incline so as to become gradually deeper from the side surface portion 2. By using the magnet pump as described above, the volume of the impeller chamber A ₁ can be increased without increasing the volume of the pump housing.

[Brief description of drawings]

FIG. 1A is a perspective view in which an impeller chamber, an impeller, and a partition wall partly cut away are disassembled, and FIG. 1B is a vertical cross-sectional side view in which the impeller chamber and the partition wall are disassembled.

FIG. 2 (A) is a partially sectional front view of the impeller chamber in which a connecting portion of the partition wall is inserted, and FIG. 2 (B) is a perspective view of the impeller chamber.

FIG. 3 is a front view of the impeller chamber.

FIG. 4 is a sectional view taken along line X ₁ -X _{1 of} FIG.

[5] (A) is X ₂ -X ₂ cross-sectional view along a line 3 (A) is X ₃ -X ₃ arrow sectional view of Fig. 3

FIG. 6 is a partial cross-sectional side view of a magnet pump in which the present invention is used.

[Explanation of symbols]

A: Housing body B ... Partition body 1 ... Inner wall 2 ... Side part 3 ... Swirl wall 4 ... Rising wall 4a ... spiral arc surface 4b ... True arc surface 5 ... Inclined recess 11 ... Connection part

Claims (2)

(57) [Claims] Consisting of 1. A perfect circular inner circumferential wall surface and the side surface portion
The impeller chamber and a substantially half of the inner peripheral wall surface of the impeller chamber so as to descend stepwise toward the inner side of the impeller chamber.
A true arcuate surface that has a spiral wall surface formed in a range of about a minute and a spiral arc surface that is continuous with the spiral wall surface inward, and that is separated from the inner peripheral wall surface and has the same core as the inner peripheral wall surface. A magnet pump, comprising: a housing body having rising wall portions formed on the outer peripheral side thereof, and a partition body having a watertightly inserted cylindrical connecting portion formed on the inner peripheral wall surface. 2. The magnet pump according to claim 1, wherein the side surface portion is formed with an inclined recessed portion that is inclined so as to become gradually deeper from near a discharge port inside a housing main body portion.