JP2004332566A - Magnet pump - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a magnet pump, wherein a pulley is mounted on a pump body in a well strong and rigid manner, magnetic force is sufficiently transmitted between a driving magnet and a driven magnet without being reduced, and a bulkhead body has sufficient strength for turnably storing an impeller. <P>SOLUTION: The magnet pump comprises a pump housing A having a pump chamber 1 and a bulkhead body storage chamber 2 having a housing opening portion 2a, the impeller B, the bulkhead body 5 having a shaft supporting portion 5a<SB>1</SB>and mounted in the bulkhead body storage chamber 2, the pulley C having an inner cylinder portion 10 and an outer cylinder portion 11, the driving magnet 14 mounted on the inner cylinder portion 10, and an impeller shaft 9 by which the impeller B is turnably supported with the joint of the pump housing A to the bulkhead body 5. A storage peripheral wall portion 2b constituting the housing opening portion 2a of the bulkhead body storage chamber 2 is inserted between the outer cylinder portion 11 and the inner cylinder portion 10. The pulley C is turnably mounted on the pump housing A via a bearing 15. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention improves the mounting strength and rigidity of the pulley to be driven by the pump on the pump body side, makes the transmission of the magnetic force between the driving magnet and the driven magnet sufficient without reducing, and makes the impeller rotatable. The present invention relates to a magnet pump capable of sufficiently securing the strength of a partition body to be stored.
[0002]
[Prior art]
Japanese Patent Application Laid-Open No. 2001-514360 discloses a magnet pump in which a driving-side magnet of a magnet coupling of a magnet pump is rotationally driven by a pulley interacting with a driving belt to rotationally drive a driven magnet in an impeller in a pump body. ). In this, a stationary container made of a thin material is present as a component. The impeller (blade) inside is housed by the pump body and the partition material (stationary container), and the driving magnet member mounted on the pulley (pulley assembly) from the outside of the partition material is the driven magnet member mounted on the impeller inside the partition material Interacts with to rotate the impeller.
[0003]
[Patent Document 1]
Special table 2001-514360
[0004]
[Problems to be solved by the invention]
In Patent Document 1, the partition material not only serves to cover the impeller together with the pump body, but also serves to rotatably support the pulley. This makes it possible to maximize the magnetic force transmission between the driving magnet and the driven magnet in the magnet coupling, and to make the pump itself extremely compact and lightweight.
[0005]
However, on the other hand, the partition wall member made of a thin material supports the belt tension applied to the pulley and sufficiently transmits magnetic force between the drive magnet located outside the partition wall member and the driven magnet inside the partition wall member. In order to support the belt tension, it is necessary to increase the strength and rigidity of the partition wall material by using a steel material or the like. For this purpose, the material of the partition wall material must be thick, and at the same time, since the partition wall material is disposed between the driving magnet and the driven magnet of the magnet coupling, the magnetic force transmission between the two magnets is performed. The magnet must be thin so as not to hinder it and satisfy the magnetic force transmission between the two magnets.
[0006]
As described above, in Patent Document 1, it is necessary to satisfy conflicting conditions of strength and rigidity of the partition wall material and transmission of magnetic force of the magnet. Further, iron powder contained in dust that has entered from the outside of the pump may adhere to and accumulate on the drive magnet mounted on the pulley side, which may reduce the transmission efficiency of the rotational magnetic force of the magnet coupling, and thus the pump The rotation of the impeller may be hindered. An object of the present invention is to make the mounting strength and rigidity of the pulley to the pump body side good, to make the pulley sufficient without reducing the magnetic force transmission between the driving magnet and the driven magnet, and to make the impeller rotatable. An object of the present invention is to ensure sufficient strength of a partition body to be stored.
[0007]
[Means for Solving the Problems]
The inventor of the present invention has conducted intensive studies to solve the above-mentioned problems. As a result, the present invention provides a pump housing body having a pump chamber and a partition body storage chamber having an opening communicating with the outside, a driven magnet, and a driven magnet. An impeller having a shaft portion and an impeller blade portion, a partition having a shaft support, and being mounted in the partition housing chamber, a pulley having an inner cylindrical portion and an outer cylindrical portion, and being mounted on the inner cylindrical portion. A drive magnet, and an impeller shaft that rotatably supports the impeller between the pump housing body and the partition body when the pump housing body is joined to the partition body. Between the pump body and the inner cylinder part, and the pulley is a magnet pump rotatably mounted on the pump housing via a bearing. It is possible to improve the strength and rigidity of the partition wall, and to reduce the transmission of magnetic force between the driving magnet and the driven magnet without reducing the magnetic force, and to secure sufficient strength of the partition body for rotatably storing the impeller. It is possible to solve the above problem.
[0008]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. The pump housing A has a pump chamber 1 and a partition wall storage chamber 2 as shown in FIG. The pump chamber 1 houses an impeller blade section 8 of an impeller B described later, and the partition body housing chamber 2 houses a driven magnet section 7 of the impeller B. The partition body storage chamber 2 is formed to have a larger inner diameter than the pump chamber 1, and a partition body 5 described later is joined to the partition body storage chamber 2. A suction passage 3 and a discharge passage 4 are formed in the pump chamber 1.
[0009]
As shown in FIG. 2, the partition body 5 is a cylindrical member formed in a substantially circular inner peripheral shape, and a flange-like portion 5b is formed around the opening of the substantially cup-shaped cylindrical housing 5a. At the outer peripheral portion of the flange-shaped portion 5b, a mounting portion 5c to be mounted on the inner wall portion of the partition wall housing chamber 2 via an O-ring 17 and a flange portion 5d forming an end of the O-ring chamber 18 are formed (FIG. 1 and 3 etc.). The mounting portion 5c is inserted and fixed to the inner wall of the partition wall housing chamber 2 in a press-fit state. The inside of the cylindrical housing 5a is a gap and is used as a storage gap 5s. The driven magnet portion 7 of the impeller is stored in the storage space 5s. Further, the bottom portion of the cylindrical筺部5a are shaft support 5a ₁ is formed, the axial end of the impeller shaft 9 to be described later is pressed.
[0010]
The partition 5 is integrally formed of a thin metal material or a synthetic resin material. In particular, when the plate thickness is appropriately reduced, magnetic force transmission between the driven magnet 7b and the drive magnet 14 described below is improved. Further, since the partition 5 only supports one end of the impeller shaft 9 in the axial direction and does not serve as a bearing for the pulley C, the load of external force is extremely small.
[0011]
As shown in FIG. 2, the impeller B is formed of a synthetic resin, a metal material, or the like, and includes a driven magnet 7 and an impeller blade 8. Its driven magnet unit 7 is composed of a rotating portion 7a and the driven magnet 7b, the the rotation portion 7a shaft支貫hole 7a ₁ is formed. A driven magnet 7b is mounted on the rotating portion 7a. The driven magnet portion 7 is stored in the storage space 5s of the partition 5. At this time, the outer periphery of the driven magnet portion 7, that is, the driven magnet 7b is in a non-contact state extremely close to the inner peripheral wall surface of the storage space 5s.
[0012]
The driven magnet section 7 and the impeller blade section 8 are integrally formed, and the impeller blade section 8 rotates together with the driven magnet section 7. The impeller blade portion 8 includes a plurality of blade pieces 8a, 8a,..., And further has an annular portion 8b formed at the tip of the plurality of blade pieces 8a, 8a,. 8c are formed continuously. Impeller shaft 9 impeller B is rotatably supported, said pump housing shaft support 1a which is formed in the pump chamber 1 A, by a shaft support 5a ₁ formed in the partition member 5, the axial direction of the impeller shaft 9 Both ends are supported, and the impeller blade section 8 is accommodated in the pump chamber 1.
[0013]
As shown in FIGS. 4A and 4C, the pulley C has an inner cylindrical portion 10 and an outer cylindrical portion 11, and one end of the inner cylindrical portion 10 and the outer cylindrical portion 11 in the axial direction is connected to each other. It is formed integrally with the pulley side wall plate 12. Specifically, the inner cylindrical portion 10 and the outer cylindrical portion 11 have a flat cylindrical shape, and the outer cylindrical portion 11 is formed at an appropriate distance from the outer periphery of the inner cylindrical portion 10. A drive magnet 14 is mounted on the inner peripheral side of the inner cylindrical portion 10. The drive magnet 14 is formed in a cylindrical shape as shown in FIGS.
[0014]
As shown in FIG. 4C, a large-diameter inner peripheral portion 10a for mounting the drive magnet 14 is formed on the inner peripheral side of the inner cylindrical portion 10. The drive magnet 14 is mounted so that the outer peripheral side surface thereof is inserted into the large-diameter inner peripheral portion 10a. The mounting area of the drive magnet 14 in the inner cylindrical portion 10 is approximately half along the axial direction. The drive magnet 14 is mounted on the inner cylindrical portion 10 from the side opposite to the side on which the pulley side wall plate 12 is formed.
[0015]
The outer peripheral side surface of the outer cylindrical portion 11 serves as a belt receiving surface, and serves to receive rotational movement from the belt. As shown in FIGS. 1 and 3, the pulley C is mounted around a housing opening 2a which is an opening of the partition wall housing chamber 2 of the pump housing A. A peripheral storage peripheral wall portion 2b constituting the housing opening 2a of the partition wall storage chamber 2 is inserted between the inner cylindrical portion 10 and the outer cylindrical portion 11. That is, the housing peripheral wall portion 2b is sandwiched between the inner cylindrical portion 10 and the outer cylindrical portion 11. The storage peripheral wall portion 2b is an outer wall portion of the partition wall storage chamber 2, and is a main portion constituting the outside of the pump housing A. A bearing 15 is mounted between the outer peripheral side surface of the storage peripheral wall portion 2b of the partition body storage chamber 2 and the inner peripheral side surface of the outer cylindrical portion 11.
[0016]
The bearing 15, as specifically shown in FIG. 1, are arranged in two rows in the axial direction, it is mounted to the housing peripheral wall 2b outer peripheral side bearing mounting portion 2b ₁ formed. The bearing mounting portion 2b _1, said an area for attachment formed in the housing opening portion 2a side toward the housing wall portion 2b, the stopper portion 2b ₁₁ and groove 2b ₁₂ for retaining ring of the bearing 15 mounted is Is formed. Then, when mounting the bearing 15 to the bearing mounting portion 2b _1, by bearing 15 abuts against the stopper portion 2b _11, so that the bearing 15 is mounted in proper position. Further, a retaining ring 16 is mounted so that the mounted bearing 15 does not fall off.
[0017]
Further, the as shown in FIG. 3 in outer cylindrical portion 11 of the bearing mount portion 11a, is formed a stopper portion 11a ₁ is adapted to the exact position of the bearing 15 in the outer cylinder portion 11 is set . Similarly, the grooves 11a ₂ as the bearing 15 on the inner peripheral side of the outer cylindrical portion 11 is fixed is formed. Thus, the pump housing A side of the bearing mounting portion 2b ₁ and the pulley C side of the bearing mounting portion 11a, stabilize the bearing 15 on the inner peripheral side of the outer tube portion 11 of the housing peripheral wall portion 2b and the pulley C of the pump housing A The pulley C is rotatable along the outer periphery of the storage peripheral wall portion 2b of the pump housing A.
[0018]
A coating member 13 is mounted on the inner peripheral side of the inner cylindrical portion 10 of the pulley C opposite to the side on which the drive magnet 14 is mounted. The covering member 13 is formed of a metal material or a synthetic resin similarly to the partition body 5. Then, the covering member 13 is fixed to the inner periphery of the inner cylindrical portion 10 by bonding or press fitting. Further, as shown in FIG. 5, the covering member 13 may be formed integrally with the pulley side wall plate 12 in the pulley C. In this type, the covering member 13 is integrally formed with the pulley side wall plate 12 by casting or the like.
[0019]
Further, the covering member 13 may be detachable from the pulley C in some cases. In this case, as shown in FIG. 6 (B), the covering member 13 has a cap shape and includes a cap top portion 13a and a cylindrical insertion side portion 13b. The fitting protrusion 13b ₁ is formed on the insertion side 13b. Also on the inner peripheral surface of the inner cylinder portion 10 fitted portion 10b of the fitting protrusions 13b ₁ is fitted is formed. Then, as shown in FIG. 6 (A), the covering member 13 is inserted into the inner peripheral surface of the inner cylinder portion 10 and the fitting projection 13b ₁ and the fitted portion 10b is fitted fixed structure It has become.
[0020]
By providing the covering member 13 on the pulley C, the openings at the 10 locations of the inner cylindrical portion from the side of the pulley side wall plate 12 are closed, and the driving magnet 14 is covered from outside the pulley C. At the opening on the inner side of the pulley C, communication with the outside is closed by a bearing 15 mounted between the outer cylindrical portion 11 and the housing peripheral wall portion 2b of the pump housing A. Due to the above and the covering member 13, the drive magnet 14 and the partition 5 arranged inside are present in a substantially closed space. With this substantially closed gap, the magnet coupling structure between the drive magnet 14 and the partition 5 can be protected from dust such as external iron powder.
[0021]
Further, by setting the distance between the inner surface of the pulley side wall plate 12 of the pulley C and the tip end of the storage peripheral wall portion 2b of the pump housing A to be large, the covering member 13 is separated from the pulley side wall plate 12. It can be prevented from protruding to the large. Further, when the pulley C is mounted, it is possible to prevent the pump housing A from being too close. The material of the pump housing A is made of an aluminum alloy, and the partition body is made of a metal material (stainless steel), a synthetic resin (PPS), or the like.
[0022]
【The invention's effect】
Claim 1 is a pump housing A having a pump chamber 1 and a partition body housing chamber 2 having a housing opening 2a communicating with the outside, an impeller B having a driven magnet section 7 and an impeller blade section 8, and a shaft support section. A partition wall 5 having a partition wall 5a ₁ and mounted in the partition wall housing chamber 2, a pulley C having an inner cylindrical portion 10 and an outer cylindrical portion 11, a driving magnet 14 mounted on the inner cylindrical portion 10; An impeller shaft 9 rotatably supported between the pump housing A and the partition 5 while the impeller B is joined to the pump housing A, and a storage peripheral wall portion 2b constituting a housing opening 2a of the partition body storage chamber 2. Is inserted between the outer cylinder part 11 and the inner cylinder part 10, and the pulley C is a magnet pump rotatably mounted on the pump housing A via a bearing 15, so that the pump The pulley C to be moved has good attachment strength and rigidity to the pump body side, and has sufficient magnetic force transmission between the driving magnet 14 and the driven magnet 7b without being reduced. The effect that the intensity | strength of the partition body 5 to accommodate can be sufficiently ensured is produced.
[0023]
The effect will be described in detail. While the driving magnet 14 is mounted on the pulley C, the pulley C is provided with a bearing 15 on the outer periphery of the housing peripheral wall 2b of the housing opening 2a in the partition wall housing chamber 2 of the pump housing A. It is attached through. As described above, since the partition 5 is not configured to be supported as the rotation center of the pulley C, no external force is applied to the partition 5.
[0024]
Therefore, the strength and rigidity of the mounting body of the pulley C can be easily obtained, and the partition wall 5 can be made thinner or made of a synthetic resin material. The magnetic force transmission of the magnet coupling structure in the magnet 7b is not reduced, and it is sufficient that the magnet 7b has the minimum strength as in the case of the conventional partition body 5, and can be easily put into practical use.
[0025]
According to a second aspect of the present invention, in the first aspect, the partition body 5 is a magnet pump formed of a thin material, and the partition body 5 is a thin material. And the transmission of magnetic force between the driven magnet 7b inside the partition 5 and the driven magnet 7b can be maximized, and can be extremely excellent.
[0026]
According to a third aspect of the present invention, there is provided the magnet pump according to the first or second aspect, wherein a coating member 13 that covers an inner circumferential side of the inner cylindrical portion 10 of the pulley C opposite to the drive magnet 14 is formed. In addition, in the magnet coupling structure of the pulley C, it is possible to prevent the outside dust of the internal combustion engine from entering the drive magnet 14. That is, it is possible to prevent a decrease in magnetic force transmission due to the accumulation of iron-based foreign matter such as iron powder in dust between the drive magnet 14 and the partition wall 5, thereby significantly improving the durability and life of the magnet pump. Can be done.
[Brief description of the drawings]
FIG. 1 is a longitudinal side view of the present invention. FIG. 2 is an exploded longitudinal side view of a component member of the present invention. FIG. 3 is an exploded longitudinal side view of a main member of the present invention. FIG. The cutaway perspective view (B) is a partially cutaway perspective view of the covering member, (C) is a longitudinal side view of the pulley, (D) is a longitudinal side view of the drive magnet, and [FIG. 5] (A) shows the pulley and the covering member. FIG. 6 (A) is a longitudinal sectional side view of a pulley of FIG. 6 (A). FIG. 6 (A) is a longitudinal sectional side view of a principal part of a type in which a covering member is detachably attached to the pulley. Is a longitudinal sectional side view of a main part with the covering member removed from the pulley of (A).
A ... pump housing B ... Impeller C ... pulley 1 ... pump chamber 2 ... partition wall body housing chamber 2a ... housing opening 2b ... housing peripheral wall 5 ... bulkhead member 5a 1 _... shaft support 7 ... driven magnet 8 ... impeller blade portions 9 ... Impeller shaft 10 ... Inner cylinder 11 ... Outer cylinder 13 ... Coating member 14 ... Driving magnet 15 ... Bearing

Claims (3)

A partition housing having a pump chamber, a partition housing chamber having a housing opening, an impeller having a driven magnet section and an impeller blade section, and a shaft support, and being mounted in the partition housing chamber. A pulley having an inner cylinder portion and an outer cylinder portion, a drive magnet mounted on the inner cylinder portion, and an impeller shaft on which the impeller is rotatably supported by joining the pump housing and the partition. And a storage peripheral wall portion forming a housing opening of the partition wall storage chamber is inserted between the outer cylinder portion and the inner cylinder portion, and the pulley is rotatably mounted on the pump housing via a bearing. A magnet pump characterized by being made. 2. The magnet pump according to claim 1, wherein the partition is formed of a thin material. 3. The magnet pump according to claim 1, wherein a coating member is formed to cover an inner peripheral side of the inner cylindrical portion of the pulley opposite to the drive magnet.

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