JP2002195170A - Variable displacement pump - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a variable displacement pump capable of changing a discharge amount due to the travel of an inner rotor in the axial direction, suppressing its elongation in the axial direction, easily ensuring tooth molding precision of an outer rotor and the inner rotor, improving the molding property, and miniaturizing the pump into a very small shape. SOLUTION: This variable displacement pump consists of a housing A, the outer rotor 11 forming an outflow hole and an inflow hole and stored in a rotor chamber 1, the inner rotor 12 movable in the axial direction in the housing A, a drive shaft 13 capable of sliding the inner rotor 12 in the axial direction and transmitting rotation, a slide member 19 insertable and slidable into inner periphery of the outer rotor 11 and provided with a pressing side part 19b coming into contact with an end face in the axial direction of the inner rotor 12 on a front side and a pressure receiving face 19d on a rear surface side, respectively, a springing member 16 pressing the inner rotor 12 onto a slide member 19 side, and an inflow part 10 introducing a part of fluid on the discharge side in the housing A and applying a fluid pressure on the pressure receive face 19d.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pump comprising an outer rotor and an inner rotor, wherein the inner rotor moves in the axial direction to change the discharge amount. The present invention relates to a variable displacement pump capable of easily ensuring the tooth forming accuracy of an inner rotor, improving the formability, and further reducing the size of the pump.

[0002]

2. Description of the Related Art Conventionally, there has been a trochoid type variable displacement pump composed of an outer rotor and an inner rotor. This is because a through-hole-shaped passage through which fluid flows in and out of the tooth bottom of the outer rotor is provided, and the outer rotor rotates and the passage is communicated with the suction port and the discharge port, respectively, so that the fluid flows from the suction side to the discharge side. It is something to move. Then, by moving the inner rotor and the outer rotor in the axial direction and changing the engagement width between the inner rotor and the outer rotor, the discharge amount of the pump can be varied. This kind of thing is JP-A-56
It disclosed in JP ─20788.

[0003]

The above-mentioned Japanese Patent Application Laid-Open No. 56-20 / 1981.
No. 788 discloses a mechanism in which a valve ring on an inner rotor and an outer rotor are moved by a pressure on a discharge side to change a mesh width and a liquid chamber, thereby changing a discharge amount. This is not only the outer rotor moves relative to the inner rotor, and a structure in which a pinion sleeve forming one side of the liquid chamber fitted with the inner rotor is moved over the inner rotor with the outer rotor Things. For this, it is necessary rotor was elongated in different axially from the outer rotor and inner rotor both engagement portion, the pump is long in the axial direction, the miniaturization of the pump has been difficult. An object of the present invention, or rotor lengthening of the pump by the structure as described above, is to prevent an increase in size of the housing.

[0004]

Means for Solving the Problems Therefore, the inventor of the present invention has intensively studied to solve the above-mentioned problems, and as a result, the present invention
A housing, an outer rotor formed with a plurality of inflow / outflow holes formed in an elongated shape along the axial direction and housed in a rotor chamber of the housing; and a shaft inside the housing while meshing with the outer rotor and the trochoid teeth. An inner rotor that is slidable in the axial direction, a drive shaft that is slidable in the axial direction and transmits the rotation, and an outer peripheral shape that is the same as the inner peripheral shape of the outer rotor and that is inserted and slid into the inner periphery of the outer rotor. and freely moving, the axial end surface abutting the pressing side of the inner rotor on the front side as well as scaling the outflow in hole comprises a slide member which pressure-receiving surface is formed on the rear side, the inner rotor It provided a resilient member for pressing the slide member side, and a inlet for applying a fluid pressure to the pressure receiving surface by introducing a portion of the fluid discharge side in the housing That by having a variable displacement pump, very to allow a variable capacitance with a simple structure, the pump can be miniaturized, it is obtained by solving the above problems.

[0005]

Embodiments of the present invention will be described below with reference to the drawings. The configuration of the present invention includes a pump housing, an outer rotor, an inner rotor, a slide member, and the like. Wherein the outer rotor, inner teeth consisting of a trochoid curve is formed on the inner peripheral side, the inner rotor, outer teeth consisting of less trochoidal curve number of teeth than the inner teeth are formed. The pump housing A includes a housing body A _1, consists of a housing lid A ₂ Metropolitan (see FIG. 1).

The housing body A ₁ has a rotor chamber 1 formed therein. A suction port 2 and a discharge port 3 are formed around the rotor chamber 1. The intake port 2, the formed as a void portion semicircular in the outer peripheral portion of the rotor chamber 1, Similarly, the ejection port 3 symmetrically with respect to the center of the rotor chamber 1 at the outer circumference of the rotor chamber 1 It is formed (see FIG. 2).

[0007] The suction port 2 is formed with a continuous suction passage 2a having a tubular shape. Similarly, the discharge port 3 is formed with a continuous discharge path 3a having a tubular shape. Further, the inner rotor accommodating chamber 4 in succession in the axial direction from the rotor chamber 1 is formed. The inner rotor storage chamber 4 is a space that is accommodated when the inner rotor 12 that can move in the axial direction moves (see FIG. 8). The inner rotor accommodating chamber 4, the inner diameter is smaller than the rotor chamber 1. Further, the continuously from the inner rotor storage chamber 4 is formed a stopper chamber 5, the bearing unit 6 continuously to the stopper chamber 5 is formed. In the stopper chamber 5,
A stopper 17 to be described later is accommodated, and a drive shaft 13 to be described later is supported by the bearing 6 (see FIG. 1).

Next, the housing lid A ₂ closes the opening side of the rotor chamber 1 of the housing body A ₁ .
The rotor chamber 1 and the sliding member housing chamber 7 which communicates is formed. The said slide member accommodation chamber 7, the slide member 19 described later is housed (see Figure 1). A support section storage chamber 8 is formed continuously with the slide member storage chamber 7. Further, a bearing portion 9 is formed continuously with the support portion storage chamber 8. Further, an inflow portion 10 is formed in the slide member storage chamber 7 (see FIGS. 1, 2, and 4). Flow join the club 10, the housing is communicated with the discharge port 3 formed in the body A _1, a portion of the discharge port 3 side of the fluid is adapted to flow into (see Fig. 9).

The outer rotor 11 has an internal tooth portion 11a having a trochoid curve formed on the inner peripheral side thereof.
2, a slit-shaped inflow / outflow hole 11b penetrating between the tooth bottom portion and the outer peripheral side surface is formed.
See FIG. 6 etc.). The inner rotor 12 has an outer tooth portion 12 having one less number of teeth on the outer circumference than the number of teeth of the inner tooth portion 11a.
a is formed. Further, boss hole 12b is formed on the inner peripheral side, the boss hole 12b in the boss side keyway 12b ₁ to
Are formed continuously in the axial direction inside the boss hole 12b (see FIGS. 1, 5, 6, etc.). Further, at one axial end of the outer rotor 11, the periphery of the opening of the boss hole 12b is expanded to form a resilient member receiving surface 12c.
The resilient member receiving surface 12c is adapted to receive a shaft end of a resilient member 16 described later.

[0010] The outer rotor 11 is rotatably accommodated in the rotor chamber 1, which is immovable with respect to and axially of the housing body A _1. Also, the inner rotor 12
As described above, the inner tooth portion 11 of the outer rotor 11
Is proper engagement and a. The drive shaft 13 is inserted into the boss hole 12b of the inner rotor 12. The drive shaft 13 has a shaft-side key groove 13 a formed therein, and has a configuration in which rotation can be transmitted through a boss-side key groove 12 b ₁ formed in a boss hole 12 b of the inner rotor 12 and a key material 14. (See FIGS. 1, 2 and 11).

Further, a seal plate 15 for closing the inner rotor 12 and the inner rotor storage chamber 4 from each other is provided (see FIGS. 1 and 3). The seal plate 15 is formed with a sliding hole 15a having the same shape as the external teeth 12a so that the external teeth 12a of the inner rotor 12 can penetrate and slide. The inner rotor 12 is slidable in the sliding hole 15a and the fluid in the rotor chamber 1 is sealed. Wherein the drive shaft 13, the flange portion 13b is formed, it is mounted so as to be immovable in the axial direction to the bearing portion 6 of the housing body A ₁ (see FIG. 1).

Further, the outer periphery of the drive shaft 13, elastic member 16 and the coil spring is mounted, the resilient direction end of the elastic onset member 16 abuts on the inner rotor 12 side, the other end Is the stopper chamber 5 of the housing body A ₁
On the side wall surface and around the opening of the bearing portion 6.
A stopper 17 surrounding the outer periphery of the resilient member 16
Is installed. The stopper 17 has a cylindrical shape, it is fixed in the receiving member 18 to the stopper chamber 5 (see FIGS. 1, 5, 6, etc.).

[0013] Then, the slide member 19 is accommodated in the slide member housing chamber 7 formed in the housing lid A ₂ side. The sliding member 19 has sliding outer teeth 19a formed on its outer periphery. The sliding outer teeth 19a have the same shape as the internal teeth 11a of the outer rotor 11, and can be inserted into the internal teeth 11a and slidable along the axial direction of the outer rotor 11. The slide member 19 is a flat pressing side portion 19b whose one end surface in the axial direction is closed. The other end is a support hole 19c formed as a cup-shaped cylindrical inner peripheral surface (see FIGS. 5 and 6). In addition, the sliding external teeth 19a
The thick portion around the opening is a pressure receiving surface 19d, which serves to receive pressure from the fluid.

The support hole 19c of the slide member 19
Is the sliding support member 20 is rotatably supported (see FIGS. 1 and 6). The slide support member 20
Is housed in the support storage chamber 8 and is formed of a cylindrical support 20a and a shaft 20b. Shaft portion 20b is supported by the bearing portion 9 formed in the housing lid A _2. The cylindrical support portion 20a is connected to the slide member 19
Is formed slightly smaller than the inner diameter of the support hole 19c, and is inserted into the support hole 19c of the slide support member 20 so that the slide member 1
Reference numeral 9 denotes a rotatable structure. A thrust bearing 21 is disposed between the cylindrical support portion 20a of the slide support member 20 and the side wall surface of the support portion storage chamber 8 on the bearing portion 9 side.

The sliding member 19 is in contact with the inner rotor 12 in the housing A at a portion facing the inner rotor 12 in the axial direction (see FIGS. 1 and 9). As described above, the slide member 19 is slidable in the inner tooth portion 11a with respect to the outer rotor 11, and
1a and the cylindrical support portion 20a are sealingly fitted to each other, and serve as one side surface (wall) of the outer rotor 11. The side surface of the outer rotor 11 is moved by the sliding member 19 and the seal plate 15 to form the outer rotor 1.
The pump space between the first rotor 1 and the inner rotor 12 is sealed.

The drive shaft 13 of the inner rotor 12 is
It is supported in the housing A axially immovably. Fluid flowing from the inflow portion 10 hits the pressure receiving surface 19d on the back side of the slide member 19, and when the discharge pressure exceeds a certain value, a pressure is generated to press the slide member 19 (FIGS. 9 and 11). , see Figure 12, etc.). As the discharge pressure increases, the back pressure applied to the pressure receiving surface 19d of the slide member 19 increases.

The movement of the slide member 19 is set according to the relationship between the load on the resilient member 16 on which the inner rotor 12 is resiliently supported in the axial direction, the internal pressure of the rotor, the discharge pressure, and the pressure receiving area of the slide member 19. Is done. When the slide member 19 moves, the inner rotor 12 is pushed, the meshing tooth width with the outer rotor 11 decreases, and the theoretical discharge amount decreases (see FIGS. 11 and 12).

[0018] pressing side 19b of the slide member 19, an air vent hole 19b ₁ is formed. The air vent hole 19b ₁ is pressed side 19b is the inner rotor 1
It is formed at a position where it comes into contact with 2. Further, the air vent hole 20b ₁ in the axial portion 20b of the slide support member 20 is formed (see FIG. 1, FIG. 8). The air vent hole 1
9b ₁ and the air vent hole 20b ₁
Is moved in the axial direction by the slide member 19 in the direction in which the gap chamber becomes narrower, the boss hole 12 of the inner rotor 12
b, the air in the space formed by the shaft end of the drive shaft 13 and the pressing side portion 19b is discharged to the outside of the pump, so that the operation of the inner rotor 12 and the slide member 19 is always improved. forms.

[0019]

First, when the inner rotor 12 rotates via the drive shaft 13 and the inner rotor 12 and the outer rotor 11 start to rotate, the gap between the inner rotor 12 and the outer rotor 11 expands and contracts. The outer rotor 1
The fluid (oil) sucked from the inflow / outflow hole 11b formed on the outer circumference of the first part 1 is discharged in the outer circumference direction in the compression step and functions as a pump.

The fluid discharged from the discharge port 3 goes to the discharge path 3a, but a part of the fluid is discharged from the discharge port 3a.
From the inflow portion 10 into the slide member storage chamber 7,
A pressure receiving surface 19d formed on the back surface of the slide member 19.
(See FIG. 11). When the discharge pressure exceeds a predetermined value, the fluid pressure applied to the pressure receiving surface 19 d causes the resilient member 16 that repels the inner rotor 12 in the axial direction.
Slide member 19 exceeds the elastic force of the inner rotor 1.
Move to side 2.

The pressure of the fluid is set by the relationship between the internal pressure of the rotor, the discharge pressure, and the area of the pressure receiving surface 19 d of the slide member 19. The slide member 19 is pushed by the inner rotor 12 when moving in the axial direction along the axial direction of the drive shaft 13, meshing teeth width between the outer rotor 11, i.e., the polymerization region is reduced. At this time, the sliding external teeth 1 of the sliding member 19 in contact with the inner rotor 12
9a gradually narrows the opening of the outflow / inflow hole 11b of the outer rotor 11, and the discharge amount of the fluid decreases.

[0022] More specifically, when the normal longitudinal length of the outlet in hole 11b is W _L, the slide member 19 by entering the range of the outlet in hole 11b moves in the axial direction, the outflow The opening area of the inlet 11b is reduced. At the position where the slide member 19 is stopped by the stopper 17, the substantial opening area of the inflow / outflow hole 11b becomes _WS . Further, in the process of the slide member 19 is moved, the substantial opening area of the outflow in hole 11b is W _M. That is,
Theoretical discharge amount is reduced.

[0023]

The invention of claim 1 according to the present invention includes a housing A, a plurality of the along the axial length hole shape outflow in hole 11b, 11
are formed and housed in the rotor chamber 1 of the housing A, and the outer rotor 1
1, an inner rotor 12 that can move in the axial direction within the housing A while meshing with the trochoid teeth, a drive shaft 13 that can slide the inner rotor 12 in the axial direction and transmits the rotation, and an outer peripheral shape that is the outer rotor. 11 freely inner periphery to the insertion and sliding the inner peripheral shape of the same of the outer rotor 11 in the axial end surface abutting the pressing side 19b of the inner rotor 12 on the front side, the receiving surface 19d on the back side Each formed slide member 19, a resilient member 16 for pressing the inner rotor 12 toward the slide member 19, and a part of the fluid on the discharge side in the housing A are introduced to the pressure receiving surface 19 d to be fluidized. With the variable displacement pump provided with the inflow section 10 for applying pressure, it is easy to secure the tooth forming shape accuracy without increasing the axial direction, and to improve the formability. Good west, an effect such as can be made very compact and thus pump.

The above effect will be described in detail. The outer rotor 11 which is fixed in the axial direction of the housing A and is rotatably held is mounted on the inner peripheral side of the outer rotor 11 (the inner tooth portion 11a side). wherein the shaft end of the inner rotor 12, and the pressure side 19b of the slide member 19 is opposed. The inner rotor 12, which is rotated by drive shaft 13 for rotationally driving the inner rotor 12 and the inner rotor 12 relative to the drive shaft 13 is obtained by a slidable structure in its axial direction .

With the structure described above, the width of engagement of the inner rotor 12 with the outer rotor 11 in the axial direction can be appropriately varied. Thereby, the pressing side portion 19b of the slide member 19 whose outer peripheral shape is the same as the internal tooth portion 11a of the outer rotor 11 forms a gap that is variable in the rotation direction and the axial direction by the outer rotor 11 and the inner rotor 12. Can be. Further, a part of the fluid on the discharge side in the housing A is introduced to the discharge side (discharge port 3 side), and the pressure receiving surface 19
d is provided with inlet 10 for applying a fluid pressure, the fluid entering the fluid join the club 10 may discharge pressure is kept constant.

As described above, since the inner rotor 12 and the slide member 19 are provided to face the outer rotor 11 and the inflow portion 10 is formed on the discharge side, the axial direction of the pump becomes longer. Therefore, since it is not necessary to lengthen the outer rotor 11 and the inner rotor 12 in the axial direction, it is easy to form the teeth of the outer rotor 11 and the inner rotor 12, and it is easy to secure the tooth forming shape accuracy, and to improve the formability. Can be good. Further, the sliding member 19 engaged with the outer rotor 11 and the inner rotor 12 meshing with each other are overlapped with the shaft member rotatably supported by the housing A, and can be reduced without increasing the axial length. The size of the pump can be reduced.

Next, according to a second aspect of the present invention, in the first aspect, a stopper 17 is provided in the housing A to regulate a moving range of the inner rotor 12 in a direction opposite to the slide member 19 in the axial direction. When the discharge pressure exceeds a predetermined value due to the operation of the pump, the inner rotor 12 can be stopped in a predetermined range by the stopper 17, and the inner rotor 1 can be stopped.
The engagement between the 2 and the outer rotor 11 and secured satisfactorily,
Pump performance can be further stabilized.

Next, the invention of claim 3, claim 1 or 2
In the pressing side portion 19 b of the slide member 19, a through hole 19 is formed in a contact portion with the inner rotor 12.
b ₁ , the inner rotor 12, the drive shaft 13 and the slide member 1
9 prevents the air from accumulating in the gap in the inner rotor 12 closed by the step 9 and slowing down the movement of the inner rotor 12 and the slide member 19 in the axial direction.

[Brief description of the drawings]

FIG. 1 is a longitudinal side view showing the structure of the present invention.

[2] X ₁ -X ₁ arrow sectional view of Fig. 1

[3] X ₂ -X ₂ cross-sectional view taken along Figure 1

[4] X ₃ -X ₃ arrow sectional view of Fig. 1

FIG. 5 is an exploded perspective view of main members in movable parts such as an outer rotor and an inner rotor.

FIG. 6 is an assembled structural view of a movable section of an outer rotor, an inner rotor, and the like in a partial cross section.

[7] X ₄ -X ₄ arrow sectional view of Fig. 1

FIG. 8 is a vertical sectional side view when the discharge amount is the smallest in the present invention.

FIG. 9 is a cross-sectional view of a main part showing a state where a part of a fluid flows to an inflow portion in the present invention

FIG. 10 is a vertical sectional front view of an essential part showing a state in which a part of a fluid flows to an inflow part in the present invention.

FIG. 11 is an enlarged longitudinal sectional side view of a main part showing a state in which a part of a fluid flows to an inflow portion in the present invention.

[12] enlarged vertical sectional side view showing a state where the pressure of the fluid is applied to the pressure receiving surface part flows into the inflow portion of the fluid in the present invention

[Explanation of symbols]

A: Housing 1 ... Rotor chamber 10 ... Inflow portion 11 ... Outer rotor 11b ... Outflow / inlet hole 12 ... Inner rotor 13 ... Drive shaft 16 ... Resilient member 17 ... Stopper 19 ... Slide member 19b ... Pressing side portion 19d ... Pressure receiving surface 19b ₁ ... through hole

Claims (3)

[Claims] 1. A housing, a plurality of elongate inflow / outflow holes formed in an axial direction and formed in an outer rotor housed in a rotor chamber of the housing, and the outer rotor and the trochoid tooth form mesh with each other. An inner rotor axially movable in the housing, a drive shaft slidably transmitting the inner rotor in the axial direction and transmitting rotation, and an outer peripheral shape that is the same as the inner peripheral shape of the outer rotor, A sliding member having a pressing side portion which is inserted into the periphery and is slidable and which is in contact with the axial end surface of the inner rotor on the front side, and a pressure receiving surface formed on the back side; a resilient member for pressing, and characterized by being provided with an inlet portion for applying a fluid pressure to the pressure receiving surface by introducing a portion of the discharge side of the fluid within the housing Variable displacement pump. 2. The variable displacement pump according to claim 1, wherein a stopper is provided in the housing to regulate a range of movement of the inner rotor in a direction axially opposite to the slide member. 3. The variable displacement pump according to claim 1, wherein an air vent hole is formed in the pressing side portion at a contact portion with the inner rotor.