阅读说明：本技术 内啮合齿轮泵 (Internal gear pump ) 是由 园崎智和 赤井洋 服部圭 伊藤贵之 于 2018-11-30 设计创作，主要内容包括：提供一种壳体和端盖的组装时的位置对齐容易、且能够防止这两个构件的分离、脱落的内啮合齿轮泵。在内啮合齿轮泵(1)中,壳体(5)和端盖(6)中的至少一方的构件是树脂组成物等的成形体,壳体(5)和端盖(6)通过使从一方的构件突出的多个突出部与另一方的构件嵌合而固定,该突出部是从固定于壳体(5)的金属制衬套(9)的从该壳体突出的突出部分,壳体(5)和端盖(6)通过经由跨越这两个构件的金属制衬套(9)穿过的螺栓(13)而一体化。(Provided is a ring gear pump which facilitates alignment of a housing and an end cover when they are assembled and prevents separation and separation of the two members. In an internal gear pump (1), at least one member of a housing (5) and an end cap (6) is a molded body of a resin composition or the like, the housing (5) and the end cap (6) are fixed by fitting a plurality of protruding portions protruding from one member into the other member, the protruding portions being protruding portions protruding from the housing of a metal bush (9) fixed to the housing (5), and the housing (5) and the end cap (6) are integrated by bolts (13) inserted through the metal bush (9) spanning both members.)

1. A ring gear pump in which an inner rotor having a plurality of external teeth is rotatably housed in an outer rotor having a plurality of internal teeth, with the external teeth meshing with the internal teeth and with the internal teeth being eccentric, and a suction-side volume chamber for sucking a liquid and a discharge-side volume chamber for discharging the liquid sucked into the suction-side volume chamber are formed between the internal teeth and the external teeth,

the internal gear pump includes: a housing having a recess for receiving the outer rotor and the inner rotor; and an end cap for closing the recess of the housing,

the housing and the end cap are fixed by fitting a plurality of projections projecting from one member to the other member.

2. A crescent gear pump according to claim 1,

at least one member of the housing and the end cap is formed of a molded body of a resin composition.

3. A crescent gear pump according to claim 1,

the housing and the end cap are integrated by passing through the fixing members of the two members via a metal bush spanning the two members,

at least 1 of the protruding portions is a protruding portion of a metal bush that protrudes from one of the housing and the end cap and is fixed to the one.

4. A crescent gear pump according to claim 1,

at least one member of the housing and the end cap is formed of a molded body of a resin composition,

the housing and the end cap are integrated by passing through the fixing members of the two members via a metal bush spanning the two members,

at least 1 of the protruding portions is a protruding portion of a metal bush that protrudes from one of the housing and the end cap and is fixed to the one.

5. A crescent gear pump according to claim 4,

the metal bush is a sintered metal bush, the molded body is an injection molded body of the resin composition,

the metal bush is integrally provided to the injection-molded body in one member of the housing and the end cap at the time of injection-molding of the injection-molded body.

6. A crescent gear pump according to claim 2 or 5,

at least 1 of the protruding portions is a claw portion protruding as a part of the molded body or the injection molded body in one member of the housing and the end cap.

7. A crescent gear pump according to claim 2 or 4,

the resin composition is prepared by using polyphenylene sulfide resin as matrix resin and mixing at least 1 selected from glass fiber, carbon fiber and inorganic filler.

8. A crescent gear pump according to claim 1,

at least one member of the housing and the end cap is a metal molded body.

9. A crescent gear pump according to claim 8,

the housing and the end cap are integrated by passing through the fixing members of the two members via a metal bush spanning the two members,

at least 1 of the protruding portions is a protruding portion of a metal bush that protrudes from one of the housing and the end cap and is fixed to the one.

10. A crescent gear pump according to claim 8,

at least 1 of the protruding portions is a claw portion protruding as a part of the molded body in one member of the housing and the end cap.

Technical Field

The present invention relates to a ring gear pump (trochoid (hereinafter, the same) pump) for pumping a liquid such as oil, water, or a chemical liquid, and particularly to a ring gear pump used in the field of industrial machinery, for example, a compressor for an air conditioner.

Background

The internal gear pump is a pump including: the outer rotor and the inner rotor having a trochoid tooth form are housed in a case in a sealed state, and function in such a manner that the inner rotor and the outer rotor fixed to the drive shaft rotate with the rotation of the drive shaft, thereby sucking and discharging liquid. As such a pump, recently, a pump having a resin housing has been known as a pump which can be manufactured at low cost by reducing a machining process (see patent document 1).

The structure of the internal gear pump will be described with reference to fig. 5. Fig. 5 is a cross-sectional view of a conventional internal gear pump. As shown in fig. 5, the pump 21 is mainly provided with a trochoid portion 24 in which an inner rotor 23 having a plurality of external teeth is accommodated in an annular outer rotor 22 having a plurality of internal teeth. The trochoid portion 24 is rotatably housed in a circular trochoid portion housing recess 25a, and the trochoid portion housing recess 25a is formed in a flanged cylindrical case 25. An end cap 26 for closing the trochoid portion housing recess 25a is fixed to the case 25. Further, a drive shaft 27 rotated by a drive source not shown penetrates and is fixed to the axial center of the inner rotor 23.

The end cap 26 is made of sintered metal, and the case 25 is an injection molded body produced by injection molding using a resin composition. The case 25 and the end cover 26 are fastened and fixed to a fixing plate 30 of the actual machine by bolts 29 inserted through metal bushes 28 provided in the case 25. The housing 25 and the end cap 26 seal the trochoid portion housing recess 25a with a flat planar shape.

Disclosure of Invention

Problems to be solved by the invention

As described above, in such a ring gear pump, the resin case and the metal end cover are bolt-fastened in a superposed state when the gear pump is mounted to a real machine. Since a resin molded product generally has low mechanical strength, the strength of the fastening portion is improved by insert molding the metal bush as described above. However, the interface between the housing and the end cover is a flat surface, and it is necessary to align the positions of the housing and the end cover by visually checking the offset of the bolt holes in the metal bush on the housing side and the end cover. Further, the housing and the end cap may be separated or detached during installation and transportation to the actual machine. In particular, when the pump is mounted to a real machine, the pump may easily come off depending on the mounting posture of the pump, and workability may be deteriorated.

The present invention has been made to solve the above-described problems, and an object thereof is to provide a ring gear pump in which the position alignment at the time of assembling the housing and the end cover is easy, separation and falling of the two members can be prevented, and the mechanical strength can be improved as necessary.

Means for solving the problems

A ring gear pump according to the present invention is a ring gear pump that houses an inner rotor having a plurality of external teeth in an outer rotor having a plurality of internal teeth, the inner rotor being rotatably housed in a state in which the external teeth mesh with the internal teeth and are eccentric, and that forms a suction-side volume chamber that sucks in a liquid and a discharge-side volume chamber that discharges the liquid sucked into the suction-side volume chamber between the internal teeth and the external teeth, the ring gear pump including: a housing having a recess for accommodating the outer rotor and the inner rotor; and an end cap that closes the recess of the housing, wherein the housing and the end cap are fixed by fitting a plurality of protruding portions protruding from one member to the other member.

Wherein at least one member of the housing and the end cap is formed of a molded body of a resin composition. Alternatively, at least one member of the housing and the end cap is formed of a metal molded body.

Wherein the housing and the end cap are integrated by a fixing member passing through a metal bush spanning the two members, and at least 1 of the protruding portions is a protruding portion of the metal bush protruding from one of the housing and the end cap and fixed to the one of the housing and the end cap.

In the aspect of using the resin composition molded body and the metal bush, the metal bush is a sintered metal bush, the molded body is an injection molded body of the resin composition, and the metal bush is integrally provided to the injection molded body at the time of injection molding of the injection molded body in one of the housing and the end cap.

Wherein at least 1 of the protruding portions is a claw portion protruding as a part of the molded body in one member of the housing and the end cap.

Wherein the resin composition is prepared by using polyphenylene sulfide (PPS) resin as matrix resin and mixing at least 1 selected from glass fiber, carbon fiber and inorganic filler.

Effects of the invention

The present invention provides a ring gear pump in which a plurality of projections projecting from one member are fitted and fixed to the other member in a housing and an end cap, and therefore, alignment at the time of assembly is easy, separation and separation of the two members can be prevented, and workability is excellent.

When at least one of the housing and the end cap is a molded body of a resin composition, the characteristics of the resin composition are effectively utilized, the alignment of the housing and the end cap at the time of assembly is facilitated, separation and falling-off of the two members can be prevented, and the workability is further improved.

In addition, in the case where at least one of the members of the case and the end cap is a metal molded body, the mechanical strength of the case and the end cap is improved, and the position alignment at the time of assembling them is easy, and separation and falling-off of the two members can be prevented.

The housing and the end cap are integrated by a fixing member inserted through a metal bush spanning the two members, and at least 1 of the protruding portions is a protruding portion of the metal bush protruding from one of the housing and the end cap and fixed to the one member. Further, the strength of the fastening portion between the housing and the end cap can be improved by the metal bush, and the fastening portion can be prevented from loosening due to creep deformation of the resin.

In the embodiment in which at least one of the housing and the end cap is a molded body of a resin composition and a metal bush is used, the metal bush is a sintered metal bush and is integrally provided to the injection molded body of the one of the housing and the end cap at the time of injection molding of the injection molded body, that is, the bush is disposed in a mold at the time of injection molding and is integrated by composite molding, so that the resin enters into a surface recess of the sintered metal of the bush and the joint strength of the two members is excellent by an anchor effect. Thus, even when a method of projecting the bush from the injection molded body such as a housing is employed, the bush can be prevented from falling off during transportation and installation.

The resin composition is a resin composition in which a PPS resin is used as a matrix resin and at least 1 selected from glass fibers, carbon fibers, and inorganic fillers is added thereto, and therefore, the resin composition is excellent in dimensional accuracy and toughness, and the above-described effects are easily obtained. Further, the oil resistance and chemical resistance are excellent, and the oil-resistant and chemical-resistant rubber composition can be used even in a high-temperature environment exceeding 120 ℃ such as a compressor.

In the case where the member of at least one of the housing and the end cap is a molded body of a resin composition, at least 1 of the protruding portions is a claw portion protruding as a part of the molded body, and therefore, the claw portion also becomes a part of the molded body made of a resin, and is easily elastically deformed, excellent in toughness, and capable of preventing breakage and the like at the time of assembly.

In addition, when at least one member of the case and the end cap is a metal molded body, at least 1 of the protruding portions is a claw portion protruding as a part of the molded body, and therefore, the claw portion also becomes a part of the metal molded body, and therefore, the mechanical strength is excellent, and breakage and the like at the time of assembly can be prevented.

Drawings

Fig. 1 is an assembled perspective view showing an example of a ring gear pump of the present invention.

Fig. 2 is an axial sectional view showing the internal gear pump of fig. 1.

Fig. 3 is an assembled perspective view showing another example of the internal gear pump of the present invention.

Fig. 4 is a completed perspective view of the internal gear pump of fig. 3.

Fig. 5 is an axial cross-sectional view of a conventional internal gear pump.

Detailed Description

The present invention relates to a ring gear pump having a trochoid portion in which an inner rotor having a plurality of outer teeth is rotatably housed in an outer rotor having a plurality of inner teeth in a state in which the outer teeth mesh with the inner teeth and are eccentric, and a suction-side volume chamber for sucking liquid and a discharge-side volume chamber for discharging liquid sucked into the suction-side volume chamber are formed between the inner teeth and the outer teeth. The internal gear pump includes: a housing having a recess for accommodating the outer rotor and the inner rotor constituting the trochoid portion; and an end cap for closing the recess of the case.

The ring gear pump of the present invention is characterized in that the housing and the end cap are fixed by fitting a plurality of projections projecting from one member into the other member. Examples of the protruding portion include a method using a metal bush fixed to a resin case and a method using a claw portion provided in a resin or metal case or an end cap.

An internal gear pump of a type using a metal bush will be described with reference to fig. 1 and 2. Fig. 1 is an assembly perspective view showing an example of a ring gear pump, and fig. 2 is an axial cross-sectional view of the ring gear pump.

As shown in fig. 1 and 2, the internal gear pump 1 includes: a trochoid portion 4 in which an inner rotor 3 is accommodated in an annular outer rotor 2; a pump housing 5a in which a circular recess (trochoid portion housing recess) 8 is formed to rotatably house the trochoid portion 4; a suction casing 5b formed with a liquid suction portion 5 c; and an end cap 6 for closing the trochoid portion housing recess 8 of the pump housing 5 a. The housing 5 is composed of two members, a pump housing 5a and a suction housing 5 b. The end cover 6 has a shape matching the outer shape of the upper surface of the housing 5 in which the trochoid portion housing recess 8 opens. 3 metal bushes 9 are fixed to the suction casing 5 b. As shown in fig. 2, the pump housing 5a, the suction housing 5b, and the end cover 6 are fixed and integrated to a fixing plate of the actual machine by bolts 13 as fixing members inserted through metal bushes 9 spanning them. The fixing member is not limited to the bolt 13, and may be, for example, a screw, a pin, or the like as long as each member can be fixed. The ring gear pump 1 has a drive shaft 11 coaxially fixed to the rotation center of the inner rotor 3.

The outer teeth of the inner rotor 3 are 1 less than the inner teeth of the outer rotor 2, and the inner rotor 3 is housed in the outer rotor 2 in an eccentric state in which the outer teeth are in inner-contact meshing with the inner teeth. Between the separation points where the rotors contact each other, the volume chambers on the intake side and the discharge side are formed in accordance with the rotational direction of the trochoid portion 4. A liquid flow path including a suction port communicating with the suction-side volume chamber and a discharge port communicating with the discharge-side volume chamber is formed in the bottom surface 8a of the trochoid portion accommodating recess 8 of the housing 5. The liquid is pumped from the discharge port through a discharge flow path in the center of the drive shaft 11 to a compression portion (not shown) at the upper side in the figure.

In the internal gear pump 1, in the suction-side volume chamber in which the volume is increased to be a negative pressure by rotating the trochoid portion 4 by the drive shaft 11, the liquid is sucked into the pump from the suction port. The suction-side volume chamber becomes a discharge-side volume chamber whose volume decreases due to the rotation of the trochoid portion 4 and whose internal pressure increases, and the liquid sucked in is discharged from the discharge-side volume chamber to the discharge port. The above-described pumping action is continuously performed by the rotation of the cycloid part 4, and the liquid is continuously pumped. Further, due to the liquid sealing effect of improving the sealing property of each volume chamber by the liquid sucked, the pressure difference generated between the volume chambers becomes large, and a large pumping action can be obtained.

In the internal gear pump of the present invention, at least one member of the housing and the end cap is a molded body (resin body) of a resin composition. This enables reduction of machining steps and low-cost production. In the internal gear pump of the present invention, in the structure using the resin case or the like, the position alignment at the time of assembling the case and the end cover is further facilitated, and separation and falling-off of these two members are prevented. In the embodiment of fig. 1 and 2, the substantially entire body of the housing 5 and the end cover 6, that is, the end cover 6, the pump housing 5a, and the suction housing 5b are resin bodies, and they are integrated by the metal bush 9 and the bolt 13. At least the member for fixing the metal bush 9 may be a resin body, and for example, the end cover 6 may be made of metal (iron, stainless steel, sintered metal, aluminum alloy, or the like).

As shown in fig. 1 and 2, the metal bush 9 is fixed to the flange portion 5d of the suction housing 5 b. The protruding portion of the metal bush 9 protruding from the suction housing 5b is fitted to the fitting portion 5e of the pump housing 5a and the fitting portion 6a of the end cap 6, whereby the alignment of these members can be easily performed. Further, by interposing the metal bush 9, even when one or both of the case 5 and the end cap 6 is made of a resin, the strength of the fastening portion of the two members can be improved, and the fastening portion can be prevented from loosening due to creep deformation of the resin. In addition, the components (the housing and the end cap) temporarily assembled at the time of mounting and transportation can be prevented from being separated and detached. Further, foreign matter can be prevented from entering the rotor portion.

It is preferable to adjust the length of the metal bush 9 so that the tip of the metal bush 9 does not protrude from the upper end surface 6b of the fitting portion 6a of the end cap 6 at the time of assembly. More preferably, the metal bush 9 has a shape in which the tip thereof is recessed from the upper end surface 6b of the fitting portion 6a of the end cap 6. This prevents the fixed plate of the actual machine from interfering with the metal bush 9.

The metal bush 9 may be made of any metal such as iron, stainless steel, or sintered metal, but is particularly preferably made of sintered metal. When the metal bush is made of sintered metal and is composite-molded (insert-molded) with the suction housing, the resin enters the surface recess of the sintered metal of the bush, and thus the metal bush is firmly joined by the anchor effect.

The pump housing is preferably configured such that the inner surface of the trochoid portion accommodation recess is formed of a resin body, and the bottom surface of the recess is formed of a metal body. As shown in fig. 2, the pump housing 5a is in sliding contact with the outer rotor 2 and the inner rotor 3 at the bottom surface 8a and the inner side surface 8b constituting the trochoid portion housing recess 8. By making the inner side surface 8b of the trochoid portion housing recess 8a resin body, the frictional wear characteristics with the outer rotor 2 are excellent. The bottom surface 8a of the trochoid portion housing recess 8 is formed of a disk-shaped metal plate 7 integrated with the pump housing 5a by composite molding. This provides superior flatness and can suppress variations in discharge performance compared to the case where the bottom surface 8a is formed of a resin. As the metal plate 7, a sintered metal body or a molten metal body (sheet metal stamping part) can be used.

The composite molding (insert molding) of the metal plate 7 as described above is facilitated by providing the casing 5 with two members, i.e., the pump casing 5a and the suction casing 5 b. In the present invention, even when the number of components is increased by separating the housing into a plurality of members in this way, the fitting structure using the plurality of projections facilitates alignment and provides excellent assembly performance. Further, the suction casing 5b is provided with a liquid suction portion 5 c. The filter 14 can be fixed by welding or the like, as necessary, at an end of the liquid suction portion 5c that serves as a communication path inlet (liquid suction port) to the suction-side volume chamber. The filter 14 prevents foreign matter from entering the pump.

In the pump housing 5a, a groove is provided in an outer peripheral portion of the trochoid portion housing recess 8, and a seal ring 12 is assembled in the groove. By assembling the gasket 12, it is possible to prevent liquid from leaking from the mating surface between the pump housing 5a and the end cap 6, and to suppress variation in the discharge amount, thereby increasing the safety factor. In addition, the seal ring 12 may be omitted when sufficient sealing performance can be ensured at the joint surfaces of the respective members of the case and the end cap.

An internal gear pump of a claw portion type will be described with reference to fig. 3 and 4. Fig. 3 is an assembly perspective view showing another example of the ring gear pump, and fig. 4 is a completed perspective view of the ring gear pump. As shown in fig. 3 and 4, the internal gear pump 1' includes: a trochoid portion 4 in which an inner rotor 3 is accommodated in an annular outer rotor 2; a housing 5 formed with a trochoid portion housing recess 8; and an end cover 6 for closing the trochoid portion housing recess 8. The end cover 6 has a shape matching the outer shape of the upper surface of the housing 5 in which the trochoid portion housing recess 8 opens. The case 5 is made of resin. The case 5 and the end cover 6 are fixed to a fixing plate of the actual machine by bolts (not shown) inserted through metal bushes 9 fixed to the case 5 and integrated. The basic structure of the pump is otherwise the same as that shown in figures 1 and 2.

In this embodiment, the metal bush 9 is not fitted to the end cap 6. On the other hand, the housing 5 is provided with 4 claw portions 10 protruding from the housing. These claw portions 10 are portions which are integrated with the housing 5 and are formed simultaneously when the housing 5 made of resin is molded. As shown in fig. 4, the claws 10 are fitted (engaged) so as to sandwich the outer periphery of the end cap 6 during assembly, and thus alignment can be easily performed. Further, since the claw portions are made of resin, they are easily elastically deformed, have excellent toughness, and can prevent breakage or the like at the time of assembly. The shape and the number of the claws 10 are not particularly limited as long as the two members can be aligned.

In each of the above embodiments, the resin composition forming the housing and the end cap mainly includes an injection-moldable synthetic resin as a base resin. Examples of the matrix resin include PPS resin, thermoplastic polyimide resin, polyetherketone resin, Polyetheretherketone (PEEK) resin, polyamideimide resin, Polyamide (PA) resin, polybutylene terephthalate (PBT) resin, polyethylene terephthalate (PET) resin, Polyethylene (PE) resin, polyacetal resin, and phenol resin. Each of these resins may be used alone, or may be a polymer alloy obtained by mixing 2 or more kinds of these resins. Among these heat-resistant resins, PPS resin is particularly preferably used because the molded article is excellent in creep resistance, load resistance, abrasion resistance, chemical resistance, and the like.

Glass fibers, carbon fibers, or inorganic fillers effective for increasing strength, increasing elasticity, increasing dimensional accuracy, imparting abrasion resistance, and removing anisotropy of injection molding shrinkage are preferably used alone or in an appropriate combination. In particular, the use of glass fibers and inorganic fillers in combination is economically excellent and has excellent frictional wear characteristics in oil.

In the present invention, a resin composition in which a linear PPS resin is used as a matrix resin and glass fibers and glass beads are mixed as a filler is particularly preferably used. This structure is excellent in oil resistance and chemical resistance, excellent in toughness, small in warpage due to removal of anisotropy of injection molding shrinkage, and greatly improved in dimensional accuracy, and is therefore particularly effective when both the end cap and the case are made of resin.

The housing and the end cap were molded by injection molding using molding pellets obtained from these materials. In the case of using the members shown in the form of fig. 1 and 2, the metal bush is disposed in a mold and integrated by composite molding at the time of molding the suction housing. In the molding of the pump housing, the metal plate is disposed in a mold and integrated by composite molding.

The housing or the end cap can also be formed as a die cast, for example. As the material, for example, a low melting point alloy such as an aluminum alloy is preferable. Examples of the aluminum alloy die-cast product include Al — Si alloys (ADC1), Al — Si — Mg alloys (ADC3), Al — Mg alloys (ADC5, ADC6), Al — Si — Cu alloys (ADC10, ADC10Z, ADC12, ADC12Z, and ADC14) prescribed in JIS H5302 (2006).

The housing or the end cap can also be formed as a sintered metal part, for example. As the sintered metal, an iron-based sintered metal or the like is preferable. More specifically, for example, an iron-based sintered metal having a pearlite phase at least in a surface layer portion and containing copper and tin for bonding iron structures to each other is preferable. In this case, the iron structures are bonded to each other by a copper-tin alloy. An example of the composition of such an iron-based sintered metal will be described. The copper-tin alloy comprises 1 to 10 wt% (preferably 1 to 8 wt%) of copper, 0.5 to 2 wt% of tin, and 0.1 to 0.5 wt% of tin% carbon, the remainder being iron-based sintered metal. The ratio of tin to copper is 1/5 or more and 1 or less by weight. Most of copper and tin in the iron-based sintered metal exist as a copper-tin alloy, and the structure of the copper monomer or the tin monomer hardly exists. For example, the ratio of the copper simple substance structure to the copper component in the sintered metal is 5 wt% or less, and the ratio of the tin simple substance structure to the tin component in the sintered metal is 0.1 wt% or less. The density of such a sintered metal part is, for example, 6.6g/cm³Above, preferably 6.8g/cm³Above, for example, 8.0g/cm³The following.

Specific examples of the combination include a combination in which the case is molded from the Al — Si — Cu-based aluminum alloy (ADC12) and the end cap is molded from the iron-based sintered metal having a pearlite phase at least in the surface layer portion or the Al — Si — Cu-based die-cast aluminum alloy (ADC 12).

In the internal gear pump of the present invention, sintered metals (iron, copper-iron, copper, stainless steel, etc.) are preferably used as the materials of the outer rotor and the inner rotor, and iron is particularly preferable from the viewpoint of cost. In addition, stainless steel or the like having high rust-proof ability may be used for the trochoid pump that pumps water, a chemical solution, or the like.

In the above, the case where the metal bush and the claw portion are used as the projecting portion has been described with reference to the drawings, but the internal gear pump of the present invention is not limited to this. For example, a method using both a metal bush and a claw portion may be adopted. In addition, any structure can be employed in which a plurality of projections projecting from one member are fitted and fixed to the other member.

Industrial applicability

The internal gear pump of the present invention can be widely used as a internal gear pump (trochoid pump) for pumping a liquid such as oil, water, or a chemical liquid because the position alignment at the time of assembling the housing and the end cover is easy and separation and falling of the two members can be prevented. For example, the pump can be used as a pump for supplying a liquid to a sliding portion of a scroll compressor for use in an electric water heater, an indoor air conditioner, and an automobile air conditioner, which use alternative Freon, carbon dioxide, or the like as a refrigerant.

Description of the reference numerals

1 internal gear pump

2 outer rotor

3 inner rotor

4 trochoid parts

5 casing

5a pump casing

5b suction housing

5c liquid intake part

5d Flange part

5e fitting part (suction casing)

6 end cap

6a fitting part (end cap)

6b upper end face

7 Metal plate

8 trochoid portion accommodating concave portion

8a bottom surface

8b inner side surface

9 Metal bushing

10 claw part

11 drive shaft

12 sealing ring

13 bolt

14 filter.