JPH11270469A - Gear pump - Google Patents

Abstract

PROBLEM TO BE SOLVED: To establish a stable discharge by feeding a fluid from the suction side to the gears with good balance at a uniform pressure. SOLUTION: A gear pump is composed of gears 10, 10 meshing together, a gear chamber 1 to accommodate them, and a casing A having a suction port 2 formed approximately along the rotary shafts 10b, 10b of these gears 10, 10 and a discharge port 3 to discharge the fluid out of the gear chamber 1 through the action of the gears 10, 10. The suction port 2 is formed as narrowing gradually from the inlet end 2a of the fluid toward the terminating end 2b.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gear pump capable of supplying a fluid at a suction side to a gear with a uniform pressure in a well-balanced manner and performing a stable discharge.

[0002]

2. Description of the Related Art A structure in which a gear pump is directly mounted on a device without providing a connection member (tube or the like) with the gear pump is provided. Some are communicated with the lubrication passage. The pump body is formed so that the directions of the passages of the suction port and the discharge port are substantially parallel to the axial direction of the pump gear of the gear.

[0003] For example, this is shown in Japanese Patent Application Laid-Open No. 63-248989. That is, according to this publication, the inner wall of the suction passage 6 is parallel to the axial direction of the gear 2. Japanese Utility Model Publication No. 27-1663 discloses a pump body for reversing the communication relationship between a suction port and a discharge port of a pump body and a suction port and a discharge port of a cover attached to both sides thereof by reversing the pump body. Are formed simply in oblique directions.

[0004]

Problems to be Solved by the Invention Japanese Patent Application Laid-Open No. 63-2489
In the case of No. 89, the inflow of the fluid into the interdental space of the gear is mainly due to the inflow of the gear from the tooth tip direction. Therefore,
In this structure in which the fluid flows in along the passage surface parallel to the gear width direction, the fluid smoothly flows in the vicinity of the suction hole, but in the vicinity of the end in the width direction of the gear farther from the suction hole. Then, the inflow gradually becomes difficult (compared to the inflow near the suction hole), and the inflow amount decreases. As a result, the inflow amount of the fluid into the interdental chamber of the gear is not uniform, the inflow balance is lost, and the fluid may not be sufficiently filled.

[0005] Further, the compressed fluid flows out toward the tooth tip of the gear also on the discharge hole side, but when the passage surface opposed thereto is formed in parallel to the axial direction of the gear similarly to the suction hole,
The flow to the discharge hole is not smooth, the pressure is different between the fluid inlet side and the terminal side end in the gear width direction, the side surface of the gear is pressed against the inner wall of the casing, wear is increased, and the durability of the pump is increased. It leads to deterioration of sex.

Further, the pressure difference of the fluid at the time of discharge (the pressure at which the fluid in the interdental chamber is discharged) becomes large, causing cavitation, and the cavitation may increase erosion on the casing. From the above, it is extremely difficult to improve the performance of the pump so as to efficiently pump the fluid by sufficiently feeding the fluid into the interdental chamber (pump volume chamber) of the gear in a well-balanced manner to suck or discharge the fluid. It was something.

In Japanese Utility Model Publication No. 27-1663, the suction port and the discharge port of the pump body are inclined in the gear direction. The inclined portion of this port secures communication with the oblique passage of the cover body attached to both sides of the pump main body, and the feature thereof is that the pump main body is inverted and the other oblique flow passage is formed. By communication, the suction and discharge of the flow path are changed with respect to the rotation shaft in one direction.

[0008] Either one of the two oblique passages provided on the cover body and the inclination of the port of the pump body communicating with each other are connected at a right angle. For this reason, the inclined portion of the port of the pump body, on the suction side, the fluid in the flow path hits the front at right angles to the inclined portion and is in a scattering state, and the flow to the gear pump chamber side is smooth. Eliminates (there is no action to positively direct fluid to the pump chamber side).

On the discharge side, the fluid discharged from the gear pump chamber flows while bending the inclined portion and the oblique flow path of the port, so that the flow to the discharge hole side is not smooth (from the pump chamber side to the discharge hole). There is no action to aim positively). The inclined portion of this port also makes the flow from the suction hole to the pump gear side and from the pump gear to the discharge hole smooth,
It is not intended to improve pump performance.

[0010]

The inventor of the present invention has made intensive studies to solve the above-mentioned problems, and as a result, has found that the present invention provides two meshing gears, a gear chamber for accommodating the two gears, and the two gears. A suction port formed substantially along the rotation axis direction of
A casing having a discharge port for discharging the fluid from the gear chamber with the gears, and the suction port is configured as a gear pump or the like that gradually narrows from the inlet end of the fluid toward the terminal end. In order to transfer the fluid from the suction port to the discharge port, the flow balance to the gears can be improved, and the pump performance can be improved.

[0011]

Embodiments of the present invention will be described below with reference to the drawings. The present invention includes a pump body A ₁ the casing A is a base cover A ₂ having a suction port 8 and a discharge port 9, and a storage cover A ₃ Prefecture. Gear chamber 1 is formed in its pump body A _1. Two gears 10, 10 are fitted in the gear chamber 1 so as to mesh with each other (see FIG. 1).

The rotating shafts 10b, 10 of the gears 10, 10
bearing portions 11, 11 of b is formed on the base cover A ₂ and housing cover A _3. The gear chamber 1 of the pump body A ₁ is provided with a pair of left and right gears 10, 10, and the pump body A ₁ is combined with the base cover A ₂ and the storage cover A ₃ to form the gear chamber 1 of the casing A. The gears 10, 10 rotate while meshing. This gear 1
The movement of the fluid F by the gears 0 and 10 and the gear chamber 1 is the same as that of a general gear pump.

When the pump body A ₁ and the base cover A ₂ are joined, the suction port 2 of the pump body A ₁
And the suction port 8 of the base cover A ₂ correspond in position, and the fluid F flowing from the suction port 8 flows into the suction port 2.
Further, the discharge port 3 and the discharge port 9 correspond in position, and the fluid F discharged from the discharge port 3 is discharged from the discharge port 9 (see FIG. 2A).

The suction port 2 is connected to the pump body A ₁
And is in communication with the gear chamber 1. Suction port 2
The rotation direction of the gears 10, 10 is the longitudinal axis of the gears 10, 10.
Ob is formed so as to be inclined with respect to the axial line SS of 0b, and the inner wall thereof has a substantially curved shape (see FIG. 2A).

[0015] The intake port 2 is referred to one side the inlet side portion of the fluid F in the longitudinal direction, i.e. the portions communicating with the suction port 8 of the base cover A ₂ and the inlet side end 2a. The other end of the suction port 2 in the longitudinal direction, that is, the end opposite to the inlet end 2a is referred to as a terminal end 2b of the suction port 2 (see FIGS. 2A and 3).

In the discharge port 3, the side on which the fluid F communicates with the discharge port 9 is referred to as an outlet side end 3a. Also,
The opposite side in the longitudinal direction of the discharge port 9 is the starting end 3b.
[See FIGS. 2 (A) and 3]. The positions where the suction port 2 and the discharge port 3 are formed are located on the center line LL where the two gears 10 and 10 mesh in the gear chamber 1 [FIG.
(B)).

The suction port 2 is provided in the longitudinal direction.
The fluid F is formed so as to become gradually narrower from the inlet end 2a toward the terminal end 2b (see FIGS. 2A and 3). As a shape in which the suction port 2 becomes gradually narrower, the front shape of the inlet side end 2a and the terminal side end 2b forms a semi-circular shape having substantially the same radius R, and with respect to the circular center point Pa of the inlet side end 2a, The circular center point Pb of the terminal end 2b is closer to the meshing point of the two gears 10, 10, ie, close to the center of the gear chamber 1 (see FIG. 4A).

The top of the inner wall of the suction port 2 is tapered along the longitudinal direction. FIG.
(B) is a three-dimensional diagram of the suction port 2 formed in a tapered shape, which is made concrete.

The taper gradient θ of the suction port 2 is about 20 °, but other than 30 °, 35 °, 40 °,
If the inclination angle is increased, the effect of flowing in the direction of the pump gear in the case of the suction side becomes larger, but it is usually about 10 °.
About 45 ° is appropriate.

Next, as another embodiment of the intake port 2, relative to the radius R _L of the semicircle of the inlet-side end 2a, to reduce the radius R _S of the semicircular termination end 2b, the inner wall May be formed into a substantially vertically conical shape [see FIGS. 5 (A) and 5 (B)]. Also in this case, the center point Pb of the semicircle of the terminal end 2b is set near the meshing point of the two gears 10, 10 with respect to the center point Pa of the semicircle of the inlet end 2a, that is, near the center of the gear chamber 1. May be brought into close proximity. Although not specifically shown,
The cross-sectional shape of the inner wall in the longitudinal direction of the suction port 2 may be a curved shape so that the inner wall is concave, in addition to the linear tapered shape.

The suction port 2 is gradually narrowed in the radial direction of the semicircle from the inlet end 2a toward the terminal end 2b, so that the fluid F is located in the center direction, that is, on the meshing position of the two gears 10, 10. Of the gears 10, 10 in the suction port 2 in the axial direction is good, and the respective fluids F can flow efficiently. The flow to the discharge port 3 can be improved.

FIGS. 11 and 12 show a state in which the force of the fluid F directed from the inlet end 2a of the suction port 2 to the terminal end 2b toward the meshing position of the two gears 10, 10 is increased. . FIG. 13 (A) shows the momentum of the fluid F at the inlet end 2a of the suction port 2 directed to the meshing position of the gears 10, 10, and FIG. 13 (B) shows the fluid at the terminal end 2b of the suction port 2. The momentum toward the meshing position of the gears 10 and 10 of F is shown, indicating that there is momentum of the fluid F at the terminal end 2b rather than the inlet end 2a.

The state of the fluid F flowing through the suction port 2 is disclosed in FIG. 10 and FIG. Suction port 2
Since the fluid F has a shape gradually narrowing from the inlet end 2a toward the terminal end 2b, the fluid F reaching the terminal end 2b is forcibly moved to the gears 10 and 10 (FIG. 1).
2, see FIG. 13).

[0024] By the suction port 2 is tapered along the longitudinal direction, the pump body A ₁ as draft when it is molded by casting, such as cast iron or an aluminum alloy, as it is used, be easily molded be able to. In addition, the inclination of the suction port 2 in the longitudinal direction is formed by offsetting the center of the arc between the inlet end 2a and the end end 2b, so that the inclination angle can be easily increased even in a limited space. Therefore, the size of the apparatus can be easily reduced.

Next, the discharge port 3 gradually narrows from the outlet end 3a toward the start end 3b (FIG. 2).
(A), see FIG. 3]. This is, in other words, the starting end 3b.
From the outlet side end 3a. The discharge port 3 has a start end 3b that is small in proximity to the meshing portion of the gears 10 and 10 when viewed in cross-sectional area, and has an outlet end 3a.
The distance from the meshing point of the gears 10 and 10 increases as the position goes (see FIG. 2B).

For this reason, the pressure fluid from the gears 10, 10 flows out from the start end 3b to the place where the cross-sectional area of the discharge port 3 is small, so that the pressure increases and the direction of the outlet end 3a having the large cross-sectional area is increased. Flow is strengthened. Also, at the outlet end 3a near the discharge port 9, the discharge port 3 has a large cross-sectional area and can smoothly flow to the discharge port 9 without increasing the pressure. In the case of increasing the inclination angle or gradually narrowing the radial direction of the semicircle, the starting end 3
Since the difference in the cross-sectional area between b and the outlet end 3a increases, the flow to the discharge port 9 is further enhanced.

Next, storage cover A ₃ is for joining the end side of the intake port 2 to the pump body A _1, it is for the terminating side of the intake port 2 and a substantially closed state. Corresponding to the shape of the terminal end 2b of the suction port 2, it has substantially the same shape portion, and both gears 10, 10 rotate, and the storage cover follows the trajectory through which the teeth 10a, 10a,. suction side recessed portion 6 is formed on the a ₃ [refer to FIG. 6 (a)]. Similarly, the gears 10 have substantially the same shape corresponding to the shape of the start end 3b of the discharge port 3, and both gears 10, 10 rotate, and their teeth 10a, 10a,.
According locus but passing the discharge side recessed portion 7 is formed in the housing cover A ₃ [refer to FIG. 6 (A)].

FIG. 6B shows the shape of the suction-side depression 6 and the discharge-side depression 7 as viewed in plan. FIG. 6 (C)
FIG. 7 is a sectional view taken along the line X ₁ -X ₁ in FIG. Here, the insertion angle α at a position that is continuous with the terminal end 2b of the suction port 2 in the suction-side recess 6 is defined as
Assuming that the angle β of the portion continuous to the 0 and 10 sides is (α> β)
It is preferable that In addition, the angle α of the suction side depression 6
Are inclined more than the taper angle of the suction port 2. The fluid F flowing from the end 2b of the suction port 2 to the recess 6 on the suction side is caused to flow toward the tooth side surfaces of the gears 10 and 10 (see FIG. 14).

In the discharge-side recess 7 on the discharge side, as shown in FIG. 6 (C), the fluid flows toward the curved surface port of the discharge port 3 due to the angle β of the portion closer to the gears 10, 10. The fluid is guided to the discharge port 3 at an angle α closer to the curved surface side and caused to flow. The fluid F can be smoothly fed out from the tooth side surfaces of the gears 10 and 10 by the inclined surface of the discharge side recessed portion 7 continuous with the discharge port 3.

[0030] Incidentally, as an embodiment, although the one provided with the suction port 8 and the discharge port 9 to the base cover A _2, as another embodiment, although not particularly shown storage cover A ₃
Or provided an inlet 8 or discharge opening 9, or a suction port 8 to the base cover A ₂ provided on the discharge port 9 provided on the housing cover A _3, there are also types of forming a port of the curved surface. There is also a type of providing a pump body A ₁ and housing cover A ₃ and the suction-side recess portion 6 and the discharge side recessed parts 7 to the side edge portions corresponding to the storage cover A ₃ which is integrally formed with.

Next, there is an embodiment in which a suction side chamfer 4 is formed along a longitudinal direction of the suction port 2 at a corner formed by the gear chamber 1 and the suction port 2 [FIGS. D) and FIG. 9]. Similarly, there is also an embodiment in which a discharge side chamfer 5 is formed along the longitudinal direction of the discharge port 3 at the corner formed by the gear chamber 1 and the discharge port 3 [FIG.
(D) and FIG. 9].

The suction side chamfer 4 is formed as a flat surface or an arc-shaped surface. Also, the suction side chamfer 4 is
It is formed larger than the ejection side chamfer 5. The surfaces of the suction side chamfer 4 and the discharge side chamfer 5 are substantially parallel to the axis SS. The chamfered portion of the suction side chamfer 4 has a ridge line 4a with the suction port 2 side and a ridge line 4a with the gear chamber 1 side.
b is not parallel but inclined. Similarly, in the chamfered portion of the discharge side chamfer 5, the ridge line 5a on the discharge port 3 side and the ridge line 5b on the gear chamber 1 side are not parallel but inclined [FIGS. 8B and 8C. )reference〕.

In the storage cover A ₃ , introduction portions 6 a, 6 a are formed so as to extend from the suction side recess 6 to the pump chamber (gear chamber 1) along the end face shape of the suction side chamfer 4. [See FIGS. 6A and 6B]. The introduction parts 6a, 6
a may be an inclined surface (see FIG. 6D). Also,
Similarly, the introduction portions 7a, 7a,
7a is formed to extend from the discharge side recess 7 to the pump chamber (gear chamber 1) [see FIGS. 6 (A) and 6 (B)]. Similarly, the introduction portions 7a, 7a may be inclined surfaces.

The inlets 6, 6 a and the inlets 7 a, 7 a extending from the suction port 2, the discharge port 3, the suction side recess 6 and the discharge side recess 7 to the gear chamber 1 are accommodated in the storage cover A _3.
And the outer peripheral edge shape is formed at the terminal end 2 of the port of the gear chamber 1.
gears 10 and 10 by matching the shape of the suction side chamfer 4 and the discharge side chamfer 5 at the start end 3b.
The communication with the entire interdental chamber (pump volume chamber) over the tooth tip and the tooth side surface at the width direction end can be made the same condition.

That is, in the case of the suction port 2, the fluid F can gradually flow from the tooth tip and the tooth side to the pump volume chamber by the introduction portions 6a and 6a along the suction side chamfer 4 (see FIG. 10). ). Similarly, in the case of the discharge port 3, it is possible to gradually flow the discharge port 3 from the tooth tip and the tooth side surface of the pump volume chamber.

The ridge line 4a between the suction side chamfer 4 and the suction port 2 side and the ridge line 5a between the discharge side chamfer 5 and the discharge port 3 side.
The inclination of “a” is inclined along the longitudinal direction of the suction port 2 and the discharge port 3. The inclination of the suction side chamfer 4 is such that the inlet side end 2a of the suction port 2 extends from the terminal side end 2b.
, The suction port 2 and the suction side chamfer 4
(See FIG. 10). Similarly, the inclination of the discharge side chamfer 5 is the same as that of the discharge port 3.
From the outlet side end 3a to the starting end side 3b, and the structure is such that the chamfered portion gradually becomes larger and the discharge side chamfer 5 and the discharge port 3 are gradually communicated. It is.

By forming the suction side chamfer 4 so as to gradually increase in width from the inlet end 2a of the suction port 2 to the terminal end 2b, for example, in the case of the suction port 2, the inlet side end is formed. Gear 1 from 2a to terminal end 2b
The flow of the fluid F toward the meshing points 0 and 10 can be further smoothed along the wide suction bevel 4.

At the inlet end 2a of the suction port 2, since the suction side chamfer 4 is a narrow portion, the fluid F suddenly flows to the meshing portion of the gears 10, 10 due to its momentum. Can be prevented. At the end 2b of the suction port 2, the suction side chamfer 4 is a large portion, so that the flow of the fluid F to the gear chamber 1 can flow more smoothly.

[0039] Further, FIG. 7, as shown in (A) to (C), the suction side recessed part 6 in the vicinity of the suction port 8 of the abutment sides of the pump body A ₁ of the base cover A ₂ 'and discharge port 9 There is an embodiment in which a discharge-side recess 7 'is formed in the vicinity. Then, the suction side chamfer 4 and the discharge side chamfer 5
Along the introduction parts 6a ', 6a' and the introduction parts 7a ', 7
a ′ may be provided.

[0040] can be provided introduction portion 6a of the housing cover A ₃ on either side of the pump body A _1, and 6a, the introduction portion 6a of the base cover A ₂ ', 6a' and on one side or both sides. Introducing portion 6a on both sides of the pump body A _1, 6a and inlet portions 6a ', 6a' by providing each can be a flow in the suction and discharge at the opposite sides of the gears 10, 10 more smoothly .

Then, the inlets 6a ', 6a' along the suction side chamfer 4 at the inlet side end 2a and the inlets 6a, 6a along the suction side chamfer 4 at the terminal end 2b. The fluid F can be caused to flow from the side surfaces of the gears 10 according to the take-out portion 4. Then, the discharge port 3 is formed such that the width of the discharge side chamfer 5 gradually increases from the outlet end 3a of the discharge port 3 toward the start end 3b.
The flow of the fluid F to the gear chamber 1 at the start end 3b is guided to the curved inner wall surface of the discharge port 3 by the large discharge side chamfer 5, and smoothly to the discharge port 9 through the inclination of the curved inner wall. Can be fluidized.

Further, in the vicinity of the discharge port 9, there is a momentum of the discharge fluid F, and it is possible to prevent a rapid flow to the discharge port 3 through the small width portion of the discharge side chamfer 5 and to make the flow smoothly. In addition to the discharge side intake unit 5, the discharge side isolation portion discharge side recessed part 7 and the inlet portion 7a formed along the 5, housing 7a to a position corresponding to the side of the gear 10, 10 cover A ₃ , It is possible to smoothly flow the suction and discharge at the side portions of the two gears 10 without abrupt flow.

FIG. 14 shows a state in which the fluid F flows in from the widthwise end side surface of the gear 10 from six suction-side recessed portions. FIG. 15 shows an embodiment in which the suction port 2 has an arc-shaped surface along the longitudinal direction, and the depression of the suction-side depression 6 has a spherical shape.

[0044]

According to the first aspect of the present invention, there is provided a gear chamber 1 in which two meshing gears 10 and 10 and two gears 10 and 10 are housed.
And a suction port 2 formed substantially along the direction of the rotating shafts 10b, 10b of the two gears 10, 10, and a discharge port 3 for discharging the fluid F from the gear chamber 1 with the gears 10, 10.
And the suction port 2
Is a gear pump formed so as to be gradually narrowed from the inlet side end 2a of the fluid F toward the terminal side end 2b, so that the inflow of the fluid F from the suction port 2 to the gears 10 It can be carried out under a uniform pressure, and as a result, cavitation can be suppressed as much as possible. Secondly, this object can be achieved with a very simple structure, and good pump performance can be obtained. it can.

The above effect will be described in detail. In a gear pump in which a suction port 2 and a discharge port 3 are provided in parallel to the axial direction of a rotating shaft 10b of the gear 10, the suction port 2 is moved from the inlet end 2a to the terminal end 2b. The suction port 2 is gradually narrowed from the inlet side end 2a of the suction port 2 to the terminal side end 2b.
The flow rate of the fluid F flowing toward the suction port 2 increases because the inner wall surface of the fluid F approaches the gears 10 and 10 provided in the gear chamber 1 at the terminal end 2b of the suction port 2.
The inflow amount of the fluid F from the terminal end 2b to the gears 10, 10 and the inflow amount at the inlet end 2a can be substantially the same.

Since the fluid F can be sufficiently filled in the interdental chamber (pump volume chamber) formed by the gear chamber 1 and the gear 10, the state in which the negative pressure element is generated in the interdental chamber is reduced. The cavitation can be suppressed, and the pump performance can be improved.

Further, the gears 10, 10
Flow of the fluid F to the
Due to the momentum of the fluid F flowing from the inlet end 2a of the suction port 2, an increase in pressure on the side surface of the gear 10 in the width direction can be reduced, and sliding wear between the gears 10, 10 and the inner wall surface of the casing A can be achieved. Can be prevented, and the durability of the pump can be improved.

Further, as described above, the suction port 2 has a structure in which the flow rate of the fluid F can be well balanced along the width direction of the gear 10 and the pressure distribution of the fluid F in the interdental chamber can be made substantially the same. This is achieved only by forming the structure such that it gradually narrows from the inlet end 2a toward the terminal end 2b, and this object can be achieved with a very simple structure.

[0049] Also, by the suction port 2 is tapered along the longitudinal direction, the pump body A ₁ when it is molded by casting, such as cast iron or an aluminum alloy, a draft the intake port 2, There is also an advantage that it can be easily used and molded easily.

Next, according to a second aspect of the present invention, in the first aspect, the suction port 2 has an arcuate inner wall,
The diameter of the arc-shaped inner wall of a is equal to the diameter of the arc-shaped inner wall of the terminal end 2b, and the center point Pb of the arc-shaped inner wall of the terminal end 2b is shifted from the center point Pa on the inlet end 2a to the gears 10 and 10 side. Due to the gear pump having the close proximity, the inner wall surface of the terminal end 2b is closer to the gears 10 and 10 than the inner wall surface of the inlet end 2a, and the width direction of the suction port 2 is gradually tapered. Therefore, the flow rate and the pressure change of the fluid F in the suction port 2 are relatively small, and the fluid F can be sent in a well-balanced manner along the width direction of the gear 10. Fluid F going to gears 10, 10
Is less likely to be turbulent, and the fluid F can be sent in a stable flow state.

Next, a third aspect of the present invention is directed to the first or second aspect.
In the above, the suction port 2 is an arc-shaped inner wall, and a gear pump in which the diameter of the arc-shaped inner wall of the end-side end 2b is smaller than the diameter of the arc-shaped inner wall of the inlet-side end 2a,
The shape of the inner wall of the suction port 2 can be substantially a half-cone shape. As a result, the fluid F traveling from the inlet end 2a toward the terminal end 2b increases the direction of the semicircle in the radial direction toward the center even at the terminal end 2b, and the opening state of the interdental chamber at the gear meshing position. Actively flow to
It is possible to efficiently fill the interdental space.

Next, according to a fourth aspect of the present invention, in the first, second or third aspect, the discharge port 3 is formed so as to be gradually narrowed from the outlet end 3a of the fluid F toward the start end 3b. With this gear pump, the flow of the fluid F at the discharge port 3 can be improved.

In the invention of claim 5, claim 1,
2, 3, or 4, a suction side chamfer 4 is formed at a corner where the suction port 2 and the gear chamber 1 intersect, and the suction side chamfer 4 extends from the inlet end 2a of the suction port 2 to the terminal end 2b.
, The fluid F can gradually flow from the suction port 2 to the gear chamber 1 from the four suction side chamfers, and at the same time, the suction side chamfer 4 Since the width of the suction port 2 is gradually increased from the inlet end 2a to the terminal end 2b of the suction port 2 along the longitudinal direction, the inflow of the fluid F at the terminal end 2b becomes smooth, and the flow to the gear chamber 1 is improved. can do.

Next, the invention of claim 6 is directed to claims 1, 2,
In 3 or 4, a discharge side chamfer 5 is formed at a corner where the discharge port 3 and the gear chamber 1 intersect, and the discharge side chamfer 5 gradually widens from the outlet end 3a toward the start end 3b. The gear chamber 1
Of the fluid F from the discharge port 3 to the discharge port 3 can be gradually performed from the five discharge side chamfers.
Is gradually widened from the outlet end 3a of the discharge port 3 to the start end 3b in the longitudinal direction, so that the fluid F flows out smoothly at the start end 3b and the flow to the discharge port 3 is good. Can be

Next, the invention of claim 7 is based on claims 1, 2,
In 3, 4, 5 or 6, wherein the casing A includes a pump body A _1, a base cover A _2, storage cover A
A _three Prefecture, said gear chamber 1, the intake port 2 and discharge port 3 is formed in the pump body A _1, near at least one side end of the inlet side or end side of the intake port 2 of the casing A, and A gap is provided between the side ends of the gears 10, 10 and the end of the suction port 2 by using a gear pump in which the suction side recessed portions 6 (6 ') are formed in the vicinity of the two gears 10, 10. be able to. And
The fluid F enters the gear 10 also from the gap created by the suction side recess 6 (6 ′), and the inflow of the fluid F can be further improved.

Next, according to an eighth aspect of the present invention, in the seventh aspect, the suction side recesses 6 (6 ') are provided with introduction portions 6a, 6a (6a', 6a ', 6a') corresponding to the suction side chamfers 4, 4. 6a ')
Are formed continuously so that the introduction portions 6a, 6a (6a ′, 6a ′,
6a ') is a gear pump formed continuously with the suction side recess 6 (6'), so that pressure fluctuation due to the throttle action during suction can be reduced and erosion is prevented beforehand. be able to.

Further, it is possible to prevent the minute fragments due to erosion from being sent to the device together with the fluid F to damage the device and to significantly reduce the durability of the device. Further, since the fluid F can be sucked into the interdental chamber of the pump gear (enhancing the filling) and the fluid F can be smoothly discharged from the interdental chamber, the filling of the interdental chamber is satisfied and the flow rate is deteriorated. Can be prevented, and the pump performance can be improved.

Next, according to a ninth aspect of the present invention, in the seventh aspect, at least in the vicinity of at least one of the outlet side or the starting end side of the fluid F at the discharge port 3 of the casing A, and the two gears 10, 10 With the gear pump having the discharge-side depression 7 formed in the vicinity, the fluid F enters the gear 10 also from the gap formed by the discharge-side depression 7, and the flow of the fluid F on the discharge side is further improved. be able to.

Next, according to a tenth aspect of the present invention, in the ninth aspect, the discharge side recessed portion 7 (7 ') is provided with introduction portions 7a, 7a (7a', 7a ', 7a ')
Are continuously formed, pressure fluctuations due to the throttle action at the time of discharging the fluid F can be reduced, and erosion can be prevented beforehand.

[Brief description of the drawings]

FIG. 1 is an exploded perspective view of the present invention with a part cut away.

FIG. 2 (A) is a longitudinal sectional side view of the present invention. FIG. 2 (B) is a front view of a suction port, a discharge port, a gear chamber, and an internally mounted gear portion.

FIG. 3 is a partially cutaway perspective view of a pump body.

FIG. 4A is a front view showing a positional relationship between a pump body, a suction port, and a discharge port. FIG.

FIG. 5A is a front view showing a positional relationship between a pump body and a suction port of another embodiment. FIG.

6A is a perspective view of a storage cover, FIG. 6B is a plan view showing a recessed portion and an introduction portion, FIG. 6C is a cross-sectional view taken along the line X ₁ -X _{1 of} FIG. X ₂ -X ₂ arrow sectional view of

7A is a perspective view of a base cover having a suction side recess and a discharge side recess. FIG. 7B is a front view showing the suction side recess and the discharge side recess. FIG. ₃ -X ₃ sectional view taken along the line

8 (A) is X ₄ -X ₄ cross-sectional view taken along a front view of the embodiment of forming the chamfered portions to the suction port and discharge port (B) is (A) (C) is a (A) X ₅ -X ₅ sectional view taken (D) is truncated and perspective view of the pump body

FIG. 9 is an enlarged perspective view of a suction side chamfer.

FIG. 10 is an operation diagram of a suction side chamfer.

FIG. 11 is a perspective view showing a state in which a fluid flows through a suction port.

FIG. 12 is a longitudinal side view showing a state in which a fluid flows through a suction port.

13A is an operation diagram showing the force of the fluid F at the inlet end of the suction port. FIG. 13A is an operation diagram showing the force of the fluid F at the terminal end of the suction port.

FIG. 14 is a longitudinal sectional side view showing a state in which a fluid flows through a suction side recess.

FIG. 15 is a drawing in which a suction port and a suction side recess are formed on an arc;
Longitudinal side view showing the state in which fluid flows

[Explanation of symbols]

A ... casing A ₁ ... pump body A ₂ ... base cover A ₃ ... housing cover F ... fluid Pa ... center point Pb ... center point 1 ... gear chamber 2 ... intake port 2a ... inlet end 2b ... terminating end 3 ... discharge Port 3a: Exit side end 3b ... Start end side 4 ... Suction side chamfer 5 ... Discharge side chamfer 6 ... Suction side recess 6a ... Introducing section 6 '... Suction side recess 6a' ... Introducing section 7 ... Discharge side recess Portion 7a: Introducing portion 7 ': Discharge side recess portion 7a': Introducing portion 10: Gear 10b: Rotating shaft

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[Procedure amendment]

[Submission date] March 8, 1999

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Full text

[Correction method] Change

[Correction contents]

[Document Name] Statement

[Title of the Invention] Gear pump

[Claims]

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gear pump capable of supplying a fluid at a suction side to a gear with a uniform pressure in a well-balanced manner and performing a stable discharge.

[0002]

2. Description of the Related Art A structure in which a gear pump is directly mounted on a device without providing a connection member (tube or the like) with the gear pump is provided. Some are communicated with the lubrication passage. The pump body is formed so that the directions of the passages of the suction port and the discharge port are substantially parallel to the axial direction of the pump gear of the gear.

[0003] For example, this is shown in Japanese Patent Application Laid-Open No. 63-248989. That is, according to this publication, the inner wall of the suction passage 6 is parallel to the axial direction of the gear 2. Japanese Utility Model Publication No. 27-1663 discloses a pump body for reversing the communication relationship between a suction port and a discharge port of a pump body and a suction port and a discharge port of a cover attached to both sides thereof by reversing the pump body. Are formed simply in oblique directions.

[0004]

Problems to be Solved by the Invention Japanese Patent Application Laid-Open No. 63-2489
In the case of No. 89, the inflow of the fluid into the interdental space of the gear is mainly due to the inflow of the gear from the tooth tip direction. Therefore,
In this structure in which the fluid flows in along the passage surface parallel to the gear width direction, the fluid smoothly flows in the vicinity of the suction hole, but in the vicinity of the end in the width direction of the gear farther from the suction hole. Then, the inflow gradually becomes difficult (compared to the inflow near the suction hole), and the inflow amount decreases. As a result, the inflow amount of the fluid into the interdental chamber of the gear is not uniform, the inflow balance is lost, and the fluid may not be sufficiently filled.

[0005] Further, the compressed fluid flows out toward the tooth tip of the gear also on the discharge hole side, but when the passage surface opposed thereto is formed in parallel to the axial direction of the gear similarly to the suction hole,
The flow to the discharge hole is not smooth, the pressure is different between the fluid inlet side and the terminal side end in the gear width direction, the side surface of the gear is pressed against the inner wall of the casing, wear is increased, and the durability of the pump is increased. It leads to deterioration of sex.

Further, the pressure difference of the fluid at the time of discharge (the pressure at which the fluid in the interdental chamber is discharged) becomes large, causing cavitation, and the cavitation may increase erosion on the casing. From the above, it is extremely difficult to improve the performance of the pump so as to efficiently pump the fluid by sufficiently feeding the fluid into the interdental chamber (pump volume chamber) of the gear in a well-balanced manner to suck or discharge the fluid. It was something.

In Japanese Utility Model Publication No. 27-1663, the suction port and the discharge port of the pump body are inclined in the gear direction. The inclined portion of this port secures communication with the oblique passage of the cover body attached to both sides of the pump main body, and the feature thereof is that the pump main body is inverted and the other oblique flow passage is formed. By communication, the suction and discharge of the flow path are changed with respect to the rotation shaft in one direction.

[0008] Either one of the two oblique passages provided on the cover body and the inclination of the port of the pump body communicating with each other are connected at a right angle. For this reason, the inclined portion of the port of the pump body, on the suction side, the fluid in the flow path hits the front at right angles to the inclined portion and is in a scattering state, and the flow to the gear pump chamber side is smooth. Eliminates (there is no action to positively direct fluid to the pump chamber side).

On the discharge side, the fluid discharged from the gear pump chamber flows while bending the inclined portion and the oblique flow path of the port, so that the flow to the discharge hole side is not smooth (from the pump chamber side to the discharge hole). There is no action to aim positively). The inclined portion of this port also makes the flow from the suction hole to the pump gear side and from the pump gear to the discharge hole smooth,
It is not intended to improve pump performance.

[0010]

The inventors of the present invention have made intensive studies to solve the above-mentioned problems, and as a result, have found that the present invention provides two meshing gears, two gear chambers for accommodating both gears, and two gears. A casing having a suction port formed substantially along the rotation axis direction of the gear and a discharge port for discharging the fluid from the gear chamber by the gear, wherein the suction port has an arc-shaped inner wall, and is formed from the inlet end of the fluid. A suction side chamfer is formed at a corner where the suction port and the gear chamber intersect, and the suction side chamfer is formed at an inlet end of the suction port. Gear pump etc., which gradually becomes wider from the end to the end side, makes it possible to improve the balance of flow to the gears when transferring fluid from the suction port to the discharge port, improving pump performance Let Bets can be, is obtained by solving the above problems.

[0011]

Embodiments of the present invention will be described below with reference to the drawings. The present invention includes a pump body A ₁ the casing A is a base cover A ₂ having a suction port 8 and a discharge port 9, and a storage cover A ₃ Prefecture. Gear chamber 1 is formed in its pump body A _1. Two gears 10, 10 are fitted in the gear chamber 1 so as to mesh with each other (see FIG. 1). And the base cover A _2, referred to as cover as an upper concept combining the housing cover A _3. That is, when simply called a cover,
A base cover A _2, refers to a storage cover A _3.

The rotating shafts 10b, 10 of the gears 10, 10
bearing portions 11, 11 of b is formed on the base cover A ₂ and housing cover A _3. The gear chamber 1 of the pump body A ₁ is provided with a pair of left and right gears 10, 10, and the pump body A ₁ is combined with the base cover A ₂ and the storage cover A ₃ to form the gear chamber 1 of the casing A. The gears 10, 10 rotate while meshing. This gear 1
The movement of the fluid F by the gears 0 and 10 and the gear chamber 1 is the same as that of a general gear pump.

When the pump body A ₁ and the base cover A ₂ are joined, the suction port 2 of the pump body A ₁
And the suction port 8 of the base cover A ₂ correspond in position, and the fluid F flowing from the suction port 8 flows into the suction port 2.
Further, the discharge port 3 and the discharge port 9 correspond in position, and the fluid F discharged from the discharge port 3 is discharged from the discharge port 9 (see FIG. 2A).

The suction port 2 is connected to the pump body A ₁
And is in communication with the gear chamber 1. Suction port 2
The rotation direction of the gears 10, 10 is the longitudinal axis of the gears 10, 10.
Ob is formed so as to be inclined with respect to the axial line SS of 0b, and the inner wall thereof has a substantially curved shape (see FIG. 2A).

[0015] The intake port 2 is referred to one side the inlet side portion of the fluid F in the longitudinal direction, i.e. the portions communicating with the suction port 8 of the base cover A ₂ and the inlet side end 2a. The other end of the suction port 2 in the longitudinal direction, that is, the end opposite to the inlet end 2a is referred to as a terminal end 2b of the suction port 2 (see FIGS. 2A and 3).

In the discharge port 3, the side on which the fluid F communicates with the discharge port 9 is referred to as an outlet side end 3a. Also,
The opposite side in the longitudinal direction of the discharge port 9 is the starting end 3b.
[See FIGS. 2 (A) and 3]. The positions where the suction port 2 and the discharge port 3 are formed are located on the center line LL where the two gears 10 and 10 mesh in the gear chamber 1 [FIG.
(B)).

The suction port 2 is provided in the longitudinal direction.
The fluid F is formed so as to become gradually narrower from the inlet end 2a toward the terminal end 2b (see FIGS. 2A and 3). As a shape in which the suction port 2 becomes gradually narrower, the front shape of the inlet side end 2a and the terminal side end 2b forms a semi-circular shape having substantially the same radius R, and with respect to the circular center point Pa of the inlet side end 2a, The circular center point Pb of the terminal end 2b is closer to the meshing point of the two gears 10, 10, ie, close to the center of the gear chamber 1 (see FIG. 4A).

The top of the inner wall of the suction port 2 is tapered along the longitudinal direction. FIG.
(B) is a three-dimensional diagram of the suction port 2 formed in a tapered shape, which is made concrete.

The taper gradient θ of the suction port 2 is about 20 °, but other than 30 °, 35 °, 40 °,
If the inclination angle is increased, the effect of flowing in the direction of the pump gear in the case of the suction side becomes larger, but it is usually about 10 °.
About 45 ° is appropriate.

Next, as another embodiment of the intake port 2, relative to the radius R _L of the semicircle of the inlet-side end 2a, to reduce the radius R _S of the semicircular termination end 2b, the inner wall May be formed into a substantially vertically conical shape [see FIGS. 5 (A) and 5 (B)]. Also in this case, the center point Pb of the semicircle of the terminal end 2b is set near the meshing point of the two gears 10, 10 with respect to the center point Pa of the semicircle of the inlet end 2a, that is, near the center of the gear chamber 1. May be brought into close proximity. Although not specifically shown,
The cross-sectional shape of the inner wall in the longitudinal direction of the suction port 2 may be a curved shape so that the inner wall is concave, in addition to the linear tapered shape.

The suction port 2 is gradually narrowed in the radial direction of the semicircle from the inlet end 2a toward the terminal end 2b, so that the fluid F is located in the center direction, that is, on the meshing position of the two gears 10, 10. Of the gears 10, 10 in the suction port 2 in the axial direction is good, and the respective fluids F can flow efficiently. The flow to the discharge port 3 can be improved.

FIGS. 11 and 12 show a state in which the force of the fluid F directed from the inlet end 2a of the suction port 2 to the terminal end 2b toward the meshing position of the two gears 10, 10 is increased. . FIG. 13 (A) shows the momentum of the fluid F at the inlet end 2a of the suction port 2 directed to the meshing position of the gears 10, 10, and FIG. 13 (B) shows the fluid at the terminal end 2b of the suction port 2. The momentum toward the meshing position of the gears 10 and 10 of F is shown, indicating that there is momentum of the fluid F at the terminal end 2b rather than the inlet end 2a.

The state of the fluid F flowing through the suction port 2 is disclosed in FIG. 10 and FIG. Suction port 2
Since the fluid F has a shape gradually narrowing from the inlet end 2a toward the terminal end 2b, the fluid F reaching the terminal end 2b is forcibly moved to the gears 10 and 10 (FIG. 1).
2, see FIG. 13).

[0024] By the suction port 2 is tapered along the longitudinal direction, the pump body A ₁ as draft when it is molded by casting, such as cast iron or an aluminum alloy, as it is used, be easily molded be able to. In addition, the inclination of the suction port 2 in the longitudinal direction is formed by offsetting the center of the arc between the inlet end 2a and the end end 2b, so that the inclination angle can be easily increased even in a limited space. Therefore, the size of the apparatus can be easily reduced.

Next, the discharge port 3 gradually narrows from the outlet end 3a toward the start end 3b (FIG. 2).
(A), see FIG. 3]. This is, in other words, the starting end 3b.
From the outlet side end 3a. The discharge port 3 has a start end 3b that is small in proximity to the meshing portion of the gears 10 and 10 when viewed in cross-sectional area, and has an outlet end 3a.
The distance from the meshing point of the gears 10 and 10 increases as the position goes (see FIG. 2B).

For this reason, the pressure fluid from the gears 10, 10 flows out from the start end 3b to the place where the cross-sectional area of the discharge port 3 is small, so that the pressure increases and the direction of the outlet end 3a having the large cross-sectional area is increased. Flow is strengthened. Also, at the outlet end 3a near the discharge port 9, the discharge port 3 has a large cross-sectional area and can smoothly flow to the discharge port 9 without increasing the pressure. In the case of increasing the inclination angle or gradually narrowing the radial direction of the semicircle, the starting end 3
Since the difference in the cross-sectional area between b and the outlet end 3a increases, the flow to the discharge port 9 is further enhanced.

Next, storage cover A ₃ is for joining the end side of the intake port 2 to the pump body A _1, it is for the terminating side of the intake port 2 and a substantially closed state. Corresponding to the shape of the terminal end 2b of the suction port 2, it has substantially the same shape portion, and both gears 10, 10 rotate, and the storage cover follows the trajectory through which the teeth 10a, 10a,. suction side recessed portion 6 is formed on the a ₃ [refer to FIG. 6 (a)]. Similarly, the gears 10 have substantially the same shape corresponding to the shape of the start end 3b of the discharge port 3, and both gears 10, 10 rotate, and their teeth 10a, 10a,.
According locus but passing the discharge side recessed portion 7 is formed in the housing cover A ₃ [refer to FIG. 6 (A)].

FIG. 6B shows the shape of the suction-side depression 6 and the discharge-side depression 7 as viewed in plan. FIG. 6 (C)
FIG. 7 is a sectional view taken along the line X ₁ -X ₁ in FIG. Here, the insertion angle α at a position that is continuous with the terminal end 2b of the suction port 2 in the suction-side recess 6 is defined as
Assuming that the angle β of the portion continuous to the 0 and 10 sides is (α> β)
It is preferable that In addition, the angle α of the suction side depression 6
Are inclined more than the taper angle of the suction port 2. The fluid F flowing from the end 2b of the suction port 2 to the recess 6 on the suction side is caused to flow toward the tooth side surfaces of the gears 10 and 10 (see FIG. 14).

In the discharge-side recess 7 on the discharge side, as shown in FIG. 6 (C), the fluid flows toward the curved surface port of the discharge port 3 due to the angle β of the portion closer to the gears 10, 10. The fluid is guided to the discharge port 3 at an angle α closer to the curved surface side and caused to flow. The fluid F can be smoothly fed out from the tooth side surfaces of the gears 10 and 10 by the inclined surface of the discharge side recessed portion 7 continuous with the discharge port 3.

[0030] Incidentally, as an embodiment, although the one provided with the suction port 8 and the discharge port 9 to the base cover A _2, as another embodiment, although not particularly shown storage cover A ₃
Or provided an inlet 8 or discharge opening 9, or a suction port 8 to the base cover A ₂ provided on the discharge port 9 provided on the housing cover A _3, there are also types of forming a port of the curved surface. There is also a type of providing a pump body A ₁ and housing cover A ₃ and the suction-side recess portion 6 and the discharge side recessed parts 7 to the side edge portions corresponding to the storage cover A ₃ which is integrally formed with.

Next, there is an embodiment in which a suction side chamfer 4 is formed along a longitudinal direction of the suction port 2 at a corner formed by the gear chamber 1 and the suction port 2 [FIGS. D) and FIG. 9]. Similarly, there is also an embodiment in which a discharge side chamfer 5 is formed along the longitudinal direction of the discharge port 3 at the corner formed by the gear chamber 1 and the discharge port 3 [FIG.
(D) and FIG. 9].

The suction side chamfer 4 is formed as a flat surface or an arc-shaped surface. Also, the suction side chamfer 4 is
It is formed larger than the ejection side chamfer 5. The surfaces of the suction side chamfer 4 and the discharge side chamfer 5 are substantially parallel to the axis SS. The chamfered portion of the suction side chamfer 4 has a ridge line 4a with the suction port 2 side and a ridge line 4a with the gear chamber 1 side.
b is not parallel but inclined. Similarly, in the chamfered portion of the discharge side chamfer 5, the ridge line 5a on the discharge port 3 side and the ridge line 5b on the gear chamber 1 side are not parallel but inclined [FIGS. 8B and 8C. )reference〕.

In the storage cover A ₃ , introduction portions 6 a, 6 a are formed so as to extend from the suction side recess 6 to the pump chamber (gear chamber 1) along the end face shape of the suction side chamfer 4. [See FIGS. 6A and 6B]. The introduction parts 6a, 6
a may be an inclined surface (see FIG. 6D). Also,
Similarly, the introduction portions 7a, 7a,
7a is formed to extend from the discharge side recess 7 to the pump chamber (gear chamber 1) [see FIGS. 6 (A) and 6 (B)]. Similarly, the introduction portions 7a, 7a may be inclined surfaces.

The inlets 6, 6 a and the inlets 7 a, 7 a extending from the suction port 2, the discharge port 3, the suction side recess 6 and the discharge side recess 7 to the gear chamber 1 are accommodated in the storage cover A _3.
And the outer peripheral edge shape is formed at the terminal end 2 of the port of the gear chamber 1.
gears 10 and 10 by matching the shape of the suction side chamfer 4 and the discharge side chamfer 5 at the start end 3b.
The communication with the entire interdental chamber (pump volume chamber) over the tooth tip and the tooth side surface at the width direction end can be made the same condition.

That is, in the case of the suction port 2, the fluid F can gradually flow from the tooth tip and the tooth side to the pump volume chamber by the introduction portions 6a and 6a along the suction side chamfer 4 (see FIG. 10). ). Similarly, in the case of the discharge port 3, it is possible to gradually flow the discharge port 3 from the tooth tip and the tooth side surface of the pump volume chamber.

The ridge line 4a between the suction side chamfer 4 and the suction port 2 side and the ridge line 5a between the discharge side chamfer 5 and the discharge port 3 side.
The inclination of “a” is inclined along the longitudinal direction of the suction port 2 and the discharge port 3. The inclination of the suction side chamfer 4 is such that the inlet side end 2a of the suction port 2 extends from the terminal side end 2b.
, The suction port 2 and the suction side chamfer 4
(See FIG. 10). Similarly, the inclination of the discharge side chamfer 5 is the same as that of the discharge port 3.
From the outlet side end 3a to the starting end side 3b, and the structure is such that the chamfered portion gradually becomes larger and the discharge side chamfer 5 and the discharge port 3 are gradually communicated. It is.

By forming the suction side chamfer 4 so as to gradually increase in width from the inlet end 2a of the suction port 2 to the terminal end 2b, for example, in the case of the suction port 2, the inlet side end is formed. Gear 1 from 2a to terminal end 2b
The flow of the fluid F toward the meshing points 0 and 10 can be further smoothed along the wide suction bevel 4.

At the inlet end 2a of the suction port 2, since the suction side chamfer 4 is a narrow portion, the fluid F suddenly flows to the meshing portion of the gears 10, 10 due to its momentum. Can be prevented. At the end 2b of the suction port 2, the suction side chamfer 4 is a large portion, so that the flow of the fluid F to the gear chamber 1 can flow more smoothly.

[0039] Further, FIG. 7, as shown in (A) to (C), the suction side recessed part 6 in the vicinity of the suction port 8 of the abutment sides of the pump body A ₁ of the base cover A ₂ 'and discharge port 9 There is an embodiment in which a discharge-side recess 7 'is formed in the vicinity. Then, the suction side chamfer 4 and the discharge side chamfer 5
Along the introduction parts 6a ', 6a' and the introduction parts 7a ', 7
a ′ may be provided.

[0040] can be provided introduction portion 6a of the housing cover A ₃ on either side of the pump body A _1, and 6a, the introduction portion 6a of the base cover A ₂ ', 6a' and on one side or both sides. Introducing portion 6a on both sides of the pump body A _1, 6a and inlet portions 6a ', 6a' by providing each can be a flow in the suction and discharge at the opposite sides of the gears 10, 10 more smoothly .

Then, the inlets 6a ', 6a' along the suction side chamfer 4 at the inlet side end 2a and the inlets 6a, 6a along the suction side chamfer 4 at the terminal end 2b. The fluid F can be caused to flow from the side surfaces of the gears 10 according to the take-out portion 4. Then, the discharge port 3 is formed such that the width of the discharge side chamfer 5 gradually increases from the outlet end 3a of the discharge port 3 toward the start end 3b.
The flow of the fluid F to the gear chamber 1 at the start end 3b is guided to the curved inner wall surface of the discharge port 3 by the large discharge side chamfer 5, and smoothly to the discharge port 9 through the inclination of the curved inner wall. Can be fluidized.

Further, in the vicinity of the discharge port 9, there is a momentum of the discharge fluid F, and it is possible to prevent a rapid flow to the discharge port 3 through the small width portion of the discharge side chamfer 5 and to make the flow smoothly. In addition to the discharge side intake unit 5, the discharge side isolation portion discharge side recessed part 7 and the inlet portion 7a formed along the 5, housing 7a to a position corresponding to the side of the gear 10, 10 cover A ₃ Is provided, it is possible to smoothly flow the suction and discharge at the side portions of the two gears 10 without abrupt flow.

FIG. 14 shows a state in which the fluid F flows in from the widthwise end side surface of the gear 10 from six suction-side recessed portions. FIG. 15 shows an embodiment in which the suction port 2 has an arc-shaped surface along the longitudinal direction, and the depression of the suction-side depression 6 has a spherical shape.

[0044]

According to the first aspect of the present invention, there is provided a gear chamber 1 in which two meshing gears 10 and 10 and two gears 10 and 10 are housed.
And a casing having a suction port 2 formed substantially along the direction of the rotating shafts 10b, 10b of the two gears 10, 10, and a discharge port 3 for discharging the fluid F from the gear chamber 1 with the two gears 10, 10. A, the suction port 2 has an arcuate inner wall and is formed so as to be close to the gear 10 side from the inlet side end 2a of the fluid F toward the terminal side end 2b. A suction side chamfer 4 is formed at a corner where the suction port 1 intersects, and the suction side chamfer 4 is formed as a gear pump having a gradually widening surface from the inlet end 2a of the suction port 2 toward the terminal end 2b. First, the flow of the fluid F from the suction port 2 to the gears 10, 10 can be performed under a uniform pressure, and thus the occurrence of cavitation can be suppressed as much as possible. Second, the structure is extremely simple. Te be able to achieve this purpose,
Good pump performance can be obtained. Further, the inflow of the fluid F at the terminal end 2b of the suction port 2 can be made smooth, and the flow to the gear chamber 1 can be made good.

The effect is described in detail. A suction side chamfer 4 is formed at a corner where the suction port 2 and the gear chamber 1 intersect. The suction side chamfer 4 extends from the inlet side end 2a of the suction port 2 to the end side. By forming the surface gradually wider toward the end 2b, the flow of the fluid F in the suction port 2 is gradually performed along the size of the width surface of the chamfered portion, and the flow into the gear 10 is smoothly and smoothly performed. it can. Further, the gear chamber 1 and the gear 10
The space between the interdental chambers (pump volume chamber) can be sufficiently filled with the fluid F, so that the state in which the negative pressure element is generated in the interdental chamber can be reduced, and the occurrence of cavitation can be suppressed. In addition, the pump performance can be improved.

Further, the gears 10, 10
Flow of the fluid F to the
Due to the momentum of the fluid F flowing from the inlet end 2a of the suction port 2, an increase in pressure on the side surface of the gear 10 in the width direction can be reduced, and sliding wear between the gears 10, 10 and the inner wall surface of the casing A can be achieved. Can be prevented, and the durability of the pump can be improved.

The suction port 2 has an arcuate inner wall, and the gear 1 moves from the inlet end 2a of the fluid F toward the terminal end 2b.
By being formed so as to be close to the zero side, the flow velocity and pressure change of the fluid F in the suction port 2 are made relatively small, and the fluid F is sent in a well-balanced manner along the width direction of the gear 10. Gears 10, 10
The flow of the fluid F toward the turbulent flow hardly occurs, and the fluid F can be sent in a stable flow state. Furthermore, the pump body A ₁ when it is molded by casting, such as cast iron or an aluminum alloy, a draft the intake port 2, there is also an advantage that can be directly used, be easily molded.

Next, according to a second aspect of the present invention, in the first aspect, the discharge port 3 is formed so as to be closer to the gear 10 from the outlet end 3a of the fluid F to the start end 3b. Then, a discharge side chamfer 5 is formed at a corner where the discharge port 3 and the gear chamber 1 intersect, and the discharge side chamfer 5 gradually becomes a wide surface from the outlet end 3a toward the start end 3b. By using a gear pump, the flow of the fluid F at the discharge port 3 can be improved, and the fluid F can be gradually discharged from the gear chamber 1 to the discharge port 3 from five discharge side chamfers. At the same time, the discharge side chamfer 5 is extended along the longitudinal direction to the outlet end 3a of the discharge port 3.
From the starting end 3b, the fluid F at the starting end 3b can flow out smoothly and the flow to the discharge port 3 can be improved.
That is, in combination with the first aspect, the flow of the fluid F to the suction port 2 and the discharge port 3 is gradually performed along the width of the chamfered portion, and the inflow to the gear 10 and the discharge port 3
There is an advantage that the flow to the surface can be made extremely smooth and good.

Next, the invention of claim 3 is directed to claim 1 or 2
In the above, the casing A is provided with a pump body A
_1, a base cover A _2, consists storage cover A ₃ Prefecture, said gear chamber 1, the intake port 2 and discharge port 3 is formed in the pump body A _1, the inlet side of the suction port 2 of the pump body A ₁ Alternatively, a gear pump in which the suction side recess 6 (6 ′) is formed in the cover near at least one of the end portions on the terminal side and near both the gears 10, 10 can be used. A gap can be provided between the side end and the end of the suction port 2. Then, the fluid F enters the gear 10 also from the gap created by the suction side recess 6 (6 ′), and the inflow of the fluid F can be further improved. That is, the fluid F can smoothly flow from the side end of the gear 10 and the flow efficiency can be further improved.

Next, according to a fourth aspect of the present invention, in the third aspect, the suction side recesses 6 (6 ') are provided with introduction portions 6a, 6a (6a', 6a ', 6a') corresponding to the suction side chamfers 4, 4. 6a ')
Are formed continuously so that the introduction portions 6a, 6a (6a ′, 6a ′,
6a ') is a gear pump formed continuously with the suction side recess 6 (6'), so that pressure fluctuation due to the throttle action during suction can be reduced and erosion is prevented beforehand. be able to.

Then, it is possible to prevent the fine fragments due to the erosion from being sent to the device together with the fluid F to damage the device and to significantly reduce the durability of the device. Further, since the fluid F can be sucked into the interdental chamber of the pump gear (enhancing the filling) and the fluid F can be smoothly discharged from the interdental chamber, the filling of the interdental chamber is satisfied and the flow rate is deteriorated. Can be prevented, and the pump performance can be improved.

Next, according to a third aspect of the present invention, in the third aspect, at least in the vicinity of at least one side end of the discharge port 3 of the pump body A ₁ on the outlet side or the starting end side of the fluid F and the two gears 10. , 10 are provided with the discharge side recess 7 so that the discharge side recess 7 is formed.
As a result, the fluid F enters the gear 10 from the gap created by the gap, and the flow of the fluid F on the discharge side can be further improved.

Next, according to a sixth aspect of the present invention, in the fifth aspect, the discharge side recesses 7 (7 ') are provided with introduction portions 7a, 7a (7a', 7a ')
Are continuously formed, pressure fluctuations due to the throttle action at the time of discharging the fluid F can be reduced, and erosion can be prevented beforehand.

The invention according to claim 7 is characterized in that the two meshing gears 10 and 10, the gear chamber 1 for accommodating the two gears 10 and 10 and the rotation shafts 10b and 10b of the two gears 10 and 10 substantially along the direction. A casing A having a suction port 2 formed as described above and a discharge port 3 for discharging the fluid F from the gear chamber 1 with the two gears 10, 10. At least one of the suction port 2 and the discharge port 3 is provided. Gear 10
The casing A is formed so as to be close to the side.
A pump body A _1, consists of a base cover A ₂ storage cover A ₃ Prefecture, said gear chamber 1, the intake port 2 and discharge port 3, formed in the pump body A _1, the pump body A ₁ of the intake port 2 Near at least one of the side ends on the entrance side or the end side, and the two gears 10, 1
A gear pump in which the suction side recess 6 (6 ') is formed in the cover in the vicinity of 0, so that the suction side recess 6 (6') is formed.
The fluid F enters the gear 10 also from the gap generated by (6 ′), and the inflow of the fluid F can be further improved. That is, there is an advantage that the fluid F can flow smoothly from the side end of the gear 10 and the flow-in efficiency can be further improved.

[Brief description of the drawings]

FIG. 1 is an exploded perspective view of the present invention with a part cut away.

FIG. 2 (A) is a longitudinal sectional side view of the present invention. FIG. 2 (B) is a front view of a suction port, a discharge port, a gear chamber, and an internally mounted gear portion.

FIG. 3 is a partially cutaway perspective view of the pump body. FIG. 3A is a front view showing the positional relationship between the pump body and the suction port and the discharge port. FIG.

FIG. 4A is a front view showing a positional relationship between a pump body, a suction port, and a discharge port. FIG.

FIG. 5A is a front view showing a positional relationship between a pump body and a suction port of another embodiment. FIG.

6A is a perspective view of a storage cover, FIG. 6B is a plan view showing a recessed portion and an introduction portion, FIG. 6C is a cross-sectional view taken along the line X ₁ -X _{1 of} FIG. X ₂ -X ₂ arrow sectional view of

7A is a perspective view of a base cover having a suction side recess and a discharge side recess. FIG. 7B is a front view showing the suction side recess and the discharge side recess. FIG. ₃ -X ₃ sectional view taken along the line

8 (A) is X ₄ -X ₄ cross-sectional view taken along a front view of the embodiment of forming the chamfered portions to the suction port and discharge port (B) is (A) (C) is a (A) X ₅ -X ₅ sectional view taken (D) is truncated and perspective view of the pump body

FIG. 9 is an enlarged perspective view of a suction side chamfer.

FIG. 10 is an operation diagram of a suction side chamfer.

FIG. 11 is a perspective view showing a state in which a fluid flows through a suction port.

FIG. 12 is a longitudinal side view showing a state in which a fluid flows through a suction port.

13A is an operation diagram showing the force of the fluid F at the inlet end of the suction port. FIG. 13A is an operation diagram showing the force of the fluid F at the terminal end of the suction port.

FIG. 14 is a longitudinal sectional side view showing a state in which a fluid flows through a suction side recess.

FIG. 15 is a drawing in which a suction port and a suction side recess are formed on an arc;
Longitudinal side view showing the state in which fluid flows

[Description of Signs] A: Casing A ₁ : Pump body A ₂ : Base cover A ₃ : Storage cover F: Fluid 1: Gear chamber 2: Suction port 2a: Inlet end 2b: Terminal end 3: Discharge port 3a: Outlet side end 3b ... Start end side end 4 ... Suction side chamfer 5 ... Discharge side chamfer 6 ... Suction side depression 6a ... Introduction section 6 '... Suction side depression 6a' ... Introduction section 7 ... Discharge side depression 7a ... Introducing portion 7 ': Discharge side recessed portion 7a' ... Introducing portion 10: Gear 10b: Rotating shaft

Claims (10)

[Claims] 1. A gear meshing with two gears, a gear chamber accommodating both gears, a suction port formed substantially along the rotation axis direction of the two gears, and a discharge port discharging fluid from the gear chamber with the gears. Wherein the suction port is formed so as to be gradually narrowed from a fluid inlet end to a terminal end. 2. The suction port according to claim 1, wherein
The arc-shaped inner wall has the same diameter as the arc-shaped inner wall at the inlet end and the arc-shaped inner wall at the terminal end. A gear pump characterized by being made. 3. The suction port according to claim 1, wherein the suction port has an arcuate inner wall, and the diameter of the arcuate inner wall at the end side is smaller than the diameter of the arcuate inner wall at the inlet end. Gear pump. 4. The gear pump according to claim 1, wherein the discharge port is formed so as to be gradually narrowed from a fluid outlet end to a start end side. 5. A suction side chamfer according to claim 1, 2 or 3, wherein a suction side chamfer is formed at a corner where the suction port and the gear chamber intersect, and the suction side chamfer terminates from an inlet end of the suction port. A gear pump characterized in that the surface gradually widens toward a side end. 6. A discharge side chamfer according to claim 1, 2 or 3, wherein a discharge side chamfer is formed at a corner where the discharge port and the gear chamber intersect, and the discharge side chamfer is formed from an outlet end to a start end. A gear pump characterized in that it gradually becomes wider as it approaches. 7. The pump body according to claim 1, wherein the casing comprises a pump body, a base cover, and a storage cover, and wherein the gear chamber, the suction port and the discharge port are provided in the pump body. And a suction-side recessed portion is formed near at least one side end of the inlet port or the terminal end of the suction port of the casing, and near both gears. 8. The gear pump according to claim 7, wherein an introduction portion corresponding to the suction side chamfers 4, 4 is continuously formed in the suction side recessed portion. 9. The method according to claim 7, wherein a discharge side recess is formed near at least one side end of the fluid discharge port or the start end side in the discharge port of the casing and near both gears. And gear pump. 10. The gear pump according to claim 9, wherein an introduction portion corresponding to a discharge side chamfer is continuously formed in the discharge side recessed portion.