CN211039017U - Oil pump - Google Patents

Abstract

An oil pump comprises a first rotor assembly, an inflow channel and an outflow channel, wherein a volume cavity is arranged between the first rotor assembly and is divided into a first area and a second area, the first area is communicated with the inflow channel and is not communicated with the outflow channel, the second area is communicated with the outflow channel, and the second area is not communicated with the inflow channel; orthographic projection of the first rotor assembly, the inflow channel and the outflow channel to the direction parallel to the upper end face of the first rotor is carried out, the projection of a part of the first area is positioned in the projection of the inflow channel, the projection of the first area is not positioned in the projection of the outflow channel, and the projection of the second area is positioned in the projection of the outflow channel; this is advantageous for improving pump efficiency.

Description

Oil pump

Technical Field

The utility model relates to a vehicle field especially relates to vehicle lubricating system and/or cooling system's spare part.

Background

Oil pumps are widely used in vehicle lubrication systems and/or cooling systems and can well meet market requirements.

The oil pump mainly provides a power source for a lubricating system and/or a cooling system of a vehicle, and the pump efficiency is an important design parameter which needs to be considered in the design process of the oil pump, so that how to improve the pump efficiency is a problem which needs to be considered in the design process.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an oil pump is favorable to improving pump efficiency.

In order to achieve the above object, the present invention adopts the following technical solutions:

an oil pump comprises a first rotor assembly, a stator assembly, a second rotor assembly, a first accommodating part and a second accommodating part, wherein the first accommodating part is provided with a first accommodating cavity, the second accommodating part is provided with a second accommodating cavity, the first rotor assembly is arranged in the first accommodating cavity, and the stator assembly and the second rotor assembly are arranged in the second accommodating cavity; the oil pump comprises an inflow channel and an outflow channel, the inflow channel is used for inflow of working media, the outflow channel is used for outflow of the working media, and the inflow channel and the outflow channel are located above the first rotor assembly; the first rotor assembly comprises a first rotor and a second rotor, the first rotor is provided with a plurality of external teeth, the second rotor is provided with a plurality of internal teeth, the second rotor is positioned on the outer periphery of the first rotor, and transmission between the first rotor and the second rotor is enabled through meshing of at least part of the external teeth of the first rotor and at least part of the internal teeth of the second rotor;

a volume cavity is arranged between the outer teeth of the first rotor and the inner teeth of the second rotor; the volume chamber is divided into a first region in which a volume chamber formed between one outer tooth of the first rotor and an inner tooth of the second rotor corresponding to the outer tooth is gradually increased in volume in a rotation direction of the first rotor assembly, and a second region in which a volume chamber formed between one outer tooth of the first rotor and an inner tooth of the second rotor corresponding to the outer tooth is gradually decreased in volume in the rotation direction of the first rotor assembly; orthographically projecting the first rotor assembly toward an upper end face parallel to the first rotor, in the projection of the first rotor assembly, defining a first boundary line at which one outer tooth of the first rotor meshes with one inner tooth of the second rotor to form a first meshing point, the first boundary line being a line connecting the first meshing point with a center of the first rotor, the first boundary line being a dividing line at which the first region ends and the second region starts;

the first area is communicated with the inflow channel, the first area is not communicated with the outflow channel, the second area is communicated with the outflow channel, and the second area is not communicated with the inflow channel; orthographically projecting the first rotor assembly, the inflow channel and the outflow channel to a direction parallel to the upper end face of the first rotor, wherein a projection of a part of the first area is located in a projection of the inflow channel, a projection of the first area is not located in a projection of the outflow channel, and a projection of the second area is located in a projection of the outflow channel.

In the technical scheme, the first area is communicated with the inflow channel, the first area is not communicated with the outflow channel, the second area is communicated with the outflow channel, and the second area is not communicated with the inflow channel; orthographic projection of the first rotor assembly, the inflow channel and the outflow channel to the direction parallel to the upper end face of the first rotor is carried out, the projection of a part of the first area is positioned in the projection of the inflow channel, the projection of the first area is not positioned in the projection of the outflow channel, and the projection of the second area is positioned in the projection of the outflow channel; on one hand, the working medium in the second area is prevented from flowing to the first area through the outflow channel, so that the outlet flow loss of the pump is reduced, and the efficiency of the pump is improved; on the other hand makes in the second region partial working medium extrude to the minimum place of volume through the change of volume and then flows out along the extending direction of the passageway that outflows, has some other working medium and need not wait to extrude to the minimum place of volume and discharge again, but directly flows in the passageway that outflows through the volume chamber that corresponds and discharges to the export of oil pump again, is favorable to improving the export flow of oil pump like this relatively, and then is favorable to improving pump efficiency.

Drawings

Fig. 1 is a schematic cross-sectional view of a first embodiment of the oil pump of the present invention;

FIG. 2 is a front view schematically showing a partial structure of the oil pump of FIG. 1 without the pump cover;

FIG. 3 is a perspective view of the first housing of FIG. 1 from one perspective;

FIG. 4 is a front view of the first housing of FIG. 3;

FIG. 5 is a schematic cross-sectional view of the first housing taken along section A-A of FIG. 4;

FIG. 6 is a schematic front view of the first rotor assembly of FIG. 1 in orthographic projection onto the bottom wall of FIG. 4;

fig. 7 is a schematic cross-sectional view of a second embodiment of the oil pump of the present invention;

FIG. 8 is a schematic perspective view of the first housing of FIG. 7 in one direction;

FIG. 9 is a front view of the first housing of FIG. 8;

FIG. 10 is a schematic cross-sectional view of the first housing taken along section B-B of FIG. 9;

FIG. 11 is a schematic front view of the first rotor assembly of FIG. 7 in orthographic projection onto the bottom wall of FIG. 9;

FIG. 12 is a schematic perspective view of the pump shaft of FIG. 1 or FIG. 7;

FIG. 13 is a perspective view of the pump cap of FIG. 1 or FIG. 7 from a perspective;

FIG. 14 is a front view schematic of the pump cap of FIG. 13;

FIG. 15 is a schematic perspective view of the pump cap of FIG. 1 or FIG. 7 from another perspective;

FIG. 16 is a front view schematic of the pump cap of FIG. 15;

FIG. 17 is a front view schematic diagram of the first rotor assembly of FIG. 1 or FIG. 7 and a pump cap projected toward the lower end face of the pump cap of FIG. 16;

FIG. 18 is a schematic perspective view of the second embodiment of the pump cap of FIG. 1 or FIG. 7 in one direction;

fig. 19 is a front view of the pump cap of fig. 18.

Detailed Description

The invention will be further described with reference to the following drawings and specific embodiments:

the oil pump in the embodiment can mainly provide flowing power for the working medium of the vehicle lubricating system and/or cooling system, and particularly can provide flowing power for the working medium of the lubricating system and/or cooling system in the vehicle transmission system.

Referring to fig. 1, the oil pump 100 includes a pump housing, a first rotor assembly 1, a stator assembly 4, a second rotor assembly 2, a pump shaft 3, and an electric control plate 5; the first rotor assembly 1, the second rotor assembly 2, the stator assembly 4 and the electric control plate 5 are arranged along the axial direction of the oil pump 100, and the second rotor assembly 2 is positioned between the first rotor assembly 1 and the electric control plate 5; the oil pump 100 has a first accommodating part 80 and a second accommodating part 90, the first accommodating part 80 has a first accommodating cavity 800, the second accommodating part 90 has a second accommodating cavity 900, the first rotor assembly 1 is located in the first accommodating cavity 800, and the stator assembly 4 and the second rotor assembly 2 are located in the second accommodating cavity 900; the stator assembly 4 is positioned at the periphery of the second rotor assembly 2, the first rotor assembly 1 is close to one end of the pump shaft 3 and is connected with the pump shaft 3, and the second rotor assembly 2 is close to the other end of the pump shaft 3 and is connected with the pump shaft 3; referring to fig. 1, the stator assembly 4 includes a stator core 41 and a coil 42, when the oil pump 100 operates, the electric control board 5 controls the current passing through the coil 42 of the stator assembly 4 to change according to a predetermined rule, so as to control the stator assembly 4 to generate a changing excitation magnetic field, the second rotor assembly 2 rotates under the action of the excitation magnetic field, the second rotor assembly 2 can directly or indirectly drive the first rotor assembly 1 to rotate, when the first rotor assembly 1 rotates, the volume of a volume cavity between the first rotor assemblies 1 changes, so that the working medium is pressed out to the outflow channel, thereby generating flowing power.

Referring to fig. 1, the pump housing includes a pump cover 6, a first housing 7 and a second housing 8, the pump cover 6 and the first housing 7, and the first housing 7 and the second housing 8 are relatively and fixedly connected; specifically, in the present embodiment, the pump cover 6 and the first housing 7 are connected by screws or bolts, but of course, the pump cover 6 and the first housing 7 may also be connected by other methods, such as inserting, clamping, and the like; the first housing 7 and the second housing 8 are connected by screws or bolts, specifically, in this embodiment, a portion of the spacer 9 is provided between the first housing 7 and the second housing 8, and the screws or bolts sequentially pass through the second housing 8, the spacer 9 and the first housing 7, so that the first housing 7 and the second housing 8 are indirectly fixedly connected, of course, the first housing 7 and the second housing 8 may also be directly fixedly connected by screws or bolts, at this time, the structure of the spacer 9 may be changed correspondingly, and at this time, the spacer 9 may be positioned by tight fitting with the inner peripheral side wall of the first housing 7; the first shell 7 and the second shell 8 are connected through screws or bolts, so that the oil pump is more convenient to disassemble and assemble, in the embodiment, the electric control board 5 is arranged in the cavity between the first shell 8 and the partition 9, so that the maintenance of the electric control board 5 in the oil pump is facilitated, and the first shell 7 and the second shell 8 can be connected through inserting, clamping or other connection modes; in addition, in the present embodiment, the first receiving portion 80 and the second receiving portion 90 are formed by a pump housing, specifically, the first receiving portion 80 is formed between the pump cover 6 and the first housing 7, and the second receiving portion 90 is formed between the first housing 7 and the second housing 8, but it is needless to say that components other than the pump housing may be directly assembled with a transmission case of an automobile without the pump housing, and in this case, a partition may be provided to support the first rotor assembly 1 on the one hand and to serve as a partition between the first receiving portion 80 and the second receiving portion 90 on the other hand.

Referring to fig. 2, in the present embodiment, the first rotor assembly 1 includes a first rotor 11 and a second rotor 12, the first rotor 11 includes a plurality of external teeth, the second rotor 12 includes a plurality of internal teeth, the first rotor 11 is fixedly connected to the pump shaft 3 in fig. 1, the second rotor 12 is located on the outer periphery of the first rotor 11, a volume cavity 801 is provided between the external teeth of the first rotor 11 and the internal teeth of the second rotor 12, and the volume cavity 801 is also a part of the first accommodating cavity; in this embodiment, a certain eccentricity exists between the first rotor 11 and the second rotor 12, and when the first rotor 11 rotates, at least part of external teeth of the first rotor 11 is meshed with at least part of internal teeth of the second rotor 12, so that the first rotor 11 can drive the second rotor 12 to rotate. Referring again to fig. 1 and 2, the oil pump 100 further includes an inlet passage 61 and an outlet passage 62, the inlet passage 61 is used for inflow of the working medium, the outlet passage 62 is used for outflow of the working medium, specifically, the working medium can enter the volume chamber 801 through the inlet passage 61, and the working medium can leave the volume chamber 801 through the outlet passage 62; in this embodiment, the inflow channel 61 and the outflow channel 62 are both formed on the pump cover 6, and certainly, when the pump cover 6 is not included, other parts except the pump cover 6 can be directly assembled with a transmission case of an automobile, and at this time, the inflow channel 61 and the outflow channel 62 can be correspondingly arranged on the transmission case; referring to fig. 2, during one rotation of the first rotor assembly 1, the volume of the volume chamber formed between the outer teeth of at least one first rotor 11 and the inner teeth of the second rotor 12 corresponding to the outer teeth is changed, and, in particular, during the process of rotating the first rotor assembly 1 from the beginning to a certain angle, the volume of the volume chamber formed between the outer teeth of at least one first rotor 11 and the inner teeth of the second rotor 12 corresponding to the outer teeth gradually increases to form a partial vacuum, and at this time, the working medium is sucked into the volume chamber 801 from the inflow channel 61, during the continuous rotation of the first rotor 11 and the second rotor 12, the volume of the volume chamber formed between the external teeth of at least one first rotor 11 and the internal teeth of the second rotor 12 corresponding to the external teeth is gradually reduced, the working medium is squeezed, so that the working medium entering the volume 801 is pressed out to the outflow channel 62 to generate the motive force for flow.

Referring to fig. 1, the first receiving portion 80 includes a bottom wall 802, the bottom wall 802 being capable of supporting the first rotor assembly 1, the first receiving chamber 800 being located at one side of the bottom wall 802, and the second receiving chamber 900 being located at the other side of the bottom wall 802; the oil pump 100 further comprises a first passage 10, the first passage 10 penetrates through the upper and lower surfaces of the bottom wall 802, the first passage 10 can communicate with the first accommodating cavity 800 and the second accommodating cavity 900, the first accommodating cavity 800 can be communicated with a working medium, and at least part of the working medium in the first accommodating cavity 800 can flow into the second accommodating cavity 900 through the first passage 10 and contact with at least part of the stator assembly 4 in the second accommodating cavity 900; the oil pump 100 further includes a second passage 20, the second passage 20 being provided to penetrate a first end surface of the pump shaft 3 and a second end surface of the pump shaft 3; the oil pump 100 further includes a branch passage 64, the branch passage 64 communicates with the outflow passage 62, the second passage 20 communicates with the outflow passage 62 through the branch passage 64, and the working medium in the second receiving chamber 900 can exit the second receiving chamber 900 through the second passage 20; the outlet 201 of the second passage 20 is closer to the inlet passage 61 than the inlet 101 of the first passage 10, and the pressure of the working medium at the outlet 201 of the second passage 20 is lower than the pressure of the working medium at the inlet 101 of the first passage 10; therefore, a pressure difference is formed between the working medium at the inlet 101 of the first channel 10 and the outlet of the second channel 20, and according to the principle that the working medium flows from a place with high pressure to a place with low pressure, the working medium in the second accommodating cavity 900 can flow towards the outlet 201 of the second channel 20, and as the stator assembly 4 is arranged in the second accommodating cavity 900, at least part of heat of the stator assembly 4 can be taken away by the flowing working medium, so that the heat dissipation of the stator assembly 4 can be facilitated, and the service life of the oil pump can be prolonged; for a detailed description of the "outflow channel 62" and the "bypass channel 64", see below.

Referring to fig. 1, the first housing 7 further includes a pump shaft supporting portion 72, the pump shaft supporting portion 72 is integrally formed with the bottom wall 802, the pump shaft supporting portion 72 is convexly disposed from the lower surface of the bottom wall 802 to a direction away from the lower surface of the bottom wall 802, the pump shaft 3 passes through the pump shaft supporting portion 72, and the second channel 20 communicates the second accommodating chamber 900 with the branch channel 64; this arrangement of the second channel 20 on the pump shaft 3 is relatively simple.

Referring to fig. 1, fig. 1 shows the flow direction of the working medium, specifically, the working medium has two flow directions, in order to better illustrate the flow direction of the working, the thick dotted line in fig. 1 is the first flow direction, the thick solid line is the second flow direction, in the first flow direction, the working medium flows into the volume chambers between the first rotor assembly 1 from the inflow channel 61, and then the working medium flows out of the volume chambers from the outflow channel 62; in the second flow direction, part of the working medium entering the volume chambers between the first rotor assemblies 1 flows into the second accommodating chamber 900 from the first passage 10, and then the working medium in the second accommodating chamber 900 flows out from the second passage 20 to the branch passage 64 and then flows out from the branch passage 64 to the outflow passage 62; in this embodiment, the inflow direction of the working medium is a vertical direction, and the outflow direction of the working medium is a horizontal direction, where the "vertical direction" and the "horizontal direction" are directions in which the oil pump is placed as shown in fig. 1.

Referring to fig. 1 to 6, fig. 1 is a schematic structural view of a first embodiment of an oil pump in the present invention, fig. 3 to 5 are schematic structural views of a first housing in fig. 1, and fig. 6 is a schematic projection view of a first rotor assembly in fig. 1 onto a bottom wall of a first accommodating portion in fig. 4 in a front projection manner; the structure of the first embodiment of the oil pump will be described in detail below.

Referring to fig. 6, a volume cavity can be formed between the external teeth of the first rotor 11 and the internal teeth of the second rotor 12, the volume cavity is divided into a first area 101 and a second area 102, and in order to better distinguish the first area 101 from the second area 102 in the drawing, referring to fig. 6, the first area 101 and the second area 102 are respectively distinguished by two different section lines, in this embodiment, the first rotor assembly rotates in a counterclockwise direction, where "counterclockwise" is seen from a top view when the oil pump without section is placed as shown in fig. 1; in the first region 101, along the rotation direction of the first rotor assembly 1, the volume of the volume chamber formed between one outer tooth of the first rotor 11 and the inner tooth of the second rotor 12 corresponding to the outer tooth is gradually increased, so that a partial vacuum can be formed in the first region 101, and in conjunction with fig. 1, the working medium is sucked into the first region 101 from the inflow channel 61; in the second region 102, along the rotation direction of the first rotor assembly 1, the volume of the volume chamber formed between one outer tooth of the first rotor 11 and the inner tooth of the second rotor 12 corresponding to the outer tooth is gradually reduced, so that the working medium is compressed in the second region 102, and the pressure of the working medium in the second region is gradually increased; referring to fig. 6, the first rotor assembly 1 is orthographically projected toward the bottom wall 802 of the first accommodating portion, and at least a part of the projection 10' of the first passage is located in the second region 102, while in the present embodiment, the pressure in the second region 102 is greater than the pressure in the second accommodating chamber 900 in fig. 1, so that the working medium to be flowed into the second accommodating chamber 900 in fig. 1 is at a place where the pressure is relatively high, and according to the principle that the working medium is flowed from a place where the pressure is high to a place where the pressure is low, at least a part of the working medium in the first accommodating chamber 800 can be flowed into the second accommodating chamber 900 through the first passage 10; referring to fig. 3 and 4, in the present embodiment, the cross section of the first channel 10 is a circular hole, but the first channel 10 may also be a square hole or other closed figures.

With reference to fig. 4 to 6, orthographically projecting the first rotor assembly 1 to the bottom wall 802 of the first containing portion, defining a first dividing line L1 in the projection of the first rotor assembly 1, at a first dividing line L, one external tooth of the first rotor 11 meshes with one internal tooth of the second rotor 12 to form a first meshing point a, a first dividing line L is a connecting line of the first meshing point a and the center O of the first rotor 11, defining a second dividing line L, at a second dividing line L, another external tooth of the first rotor 11 meshes with another internal tooth of the second rotor 12 to form a second meshing point B, a second dividing line L is a connecting line of the second meshing point B and the center O of the first rotor 11, a first dividing line L and a second dividing line 8252 are dividing lines of the first area 101 and the second area 102, wherein the first dividing line 8561 is a dividing line of the end area 101 and the start area of the second area 102 as a connecting line of the first dividing line 101 and the start area 102, a dividing line 8252 is a dividing line which is a relatively closer to the working area 90, and a working medium start area which is closer to the working area 90, and a working area which is closer to the working area 90, so that the working area 90, when the working area 90, the working area can be viewed from the working area 90, the working area can be more effectively increased, the working area can be more effectively placed counterclockwise, the working area 900, the working area 90, the working area can be placed more effectively placed from the working area 900, the working area 90, the working area can be placed more effectively placed in the working area 900, the working area 90 '2, the working area can be placed more effectively, the working area 90's 2, the working area 900, the working area when the working area can be placed more effectively.

Referring to fig. 7 to 11, fig. 7 is a schematic structural view of a second embodiment of the oil pump in the present invention, fig. 8 to 10 are schematic structural views of the first housing in fig. 7, and fig. 11 is a schematic projection view of the first rotor assembly in fig. 7 onto a bottom wall of the first receiving portion in fig. 8 in a front projection manner; the structure of the second embodiment of the oil pump will be described below.

Referring to fig. 11, a volume chamber can be formed between the outer teeth of the first rotor 11 and the inner teeth of the second rotor 12, the volume chamber is divided into a first area 101 and a second area 102, in order to better distinguish the first area 101 from the second area 102 on fig. 11, referring to fig. 11, the first area 101 and the second area 102 are respectively distinguished by two different section lines, in the present embodiment, the first rotor assembly rotates in a counterclockwise direction, where "counterclockwise" is a line formed by mounting the oil pump without section as viewed from a top view in the state of fig. 1, in the first area 101, a volume chamber formed between one outer tooth of the first rotor 11 and the inner teeth of the second rotor 12 corresponding to the outer tooth gradually increases in volume along a rotating direction of the first rotor assembly 1, so that a partial vacuum can be formed in the first area 101, when the working medium is sucked into the first area 101 from the inflow channel 61, in the first area 102, in the second area 102, in a rotating direction of the first rotor 1, a line formed by pressing the outer teeth of the meshing area 102 with the meshing area 102, and a bottom wall of the meshing area 102, and a line formed by pressing the bottom wall of the rotor assembly, wherein a line is defined as a line of a tangent line of the first rotor 102, a tangent line of a tangent to a tangent line of the first rotor 1, a tangent line of a tangent to a tangent line of the first rotor 1, a tangent line of a tangent to a tangent line of a tangent line of a tangent line of the outer teeth of a tangent line of a first rotor 1, a tangent line of a.

Referring to fig. 8 to 10, the bottom wall 802a has a first groove 71, the first groove 71 is recessed from the upper surface of the bottom wall 802a to the lower surface of the bottom wall 8012a, the first groove 71 does not penetrate through the lower surface of the bottom wall 802a, the first channel 10a is located in the first groove 71, and the first channel 10a penetrates through the bottom surface of the first groove 71 and the lower surface of the bottom wall 801'; referring to fig. 10 and 11, the first rotor assembly 1 is orthographically projected towards the bottom wall 802a, at least part of the second region 102 being located within the projection of the first recess 71; the first groove 71 is arranged, so that part of working medium of the oil pump can be located in the first groove 71 in the working process, an oil film can be formed between the first rotor assembly and the bottom wall 802a, the friction force between the first rotor assembly and the bottom wall 802a in the rotating process is reduced, and the noise caused by friction is reduced; on the other hand, in the present embodiment, since the first groove 71 is located at a place where the pressure of the volume cavity is relatively high, and the first channel 10a is disposed in the first groove 71, it is beneficial to increase the pressure difference of the working medium entering the second accommodating cavity 900, so that it is beneficial to make a part of the working medium in the first accommodating cavity 800 in fig. 7 flow into the second accommodating cavity 900.

Referring to fig. 8 to 11, the first groove 71 includes a first head 711 and a first tail 712, when the oil pump operates, the working medium flows from the first head 711 to the first tail 712 in the second area 102 along the rotation direction of the first rotor assembly, referring to fig. 11, the first rotor assembly 1 is orthographically projected to the bottom wall 802a of the first accommodating portion, the projection 711 'of the first head is closer to the first boundary line L1 than the second boundary line L2, and the projection 712' of the first tail is closer to the second boundary line L2 than the first boundary line L1, of course, the projection 711 'of the first head and the first boundary line L1 may also coincide, the projection 712' of the first tail and the second boundary line L2 may also coincide, where "coincidence" is theoretical coincidence ", while actually there may be coincidence errors in machining, all offsets within the machining errors are within the protection range of the present invention, referring to fig. 8, the first passage 10a is closer to the first rotor assembly 711, and thus the pressure difference between the working medium and the working medium is increased from the working head 711 of the working chamber 712 to the working chamber 900, which is capable of gradually increasing from the working medium flowing into the working chamber 900 along the working chamber 900, thus the working chamber 900.

Referring to fig. 8 to 11, the first groove 71 further includes a first side 713 and a second side 714, the first side 713 is closer to the central axis of the first rotor 11 than the second side 714 is, the first head portion 711 is located at one end of the first side 713 and one end of the second side 714, and the first tail portion 712 is located at the other end of the first side 713 and the other end of the second side 714; referring to fig. 8 to 11, the first side surface 713 is closer to the central axis of the first rotor 11 than the tooth bottom of the external teeth of the first rotor 11, the second side surface 714 is closer to the circumferential side wall of the first accommodating part 80 than the tooth bottom of the internal teeth of the second rotor 12, or the first rotor assembly 1 is orthographically projected to the bottom wall 801 ' of the first accommodating part, the projection 713 ' of the first side surface is tangent to the projection of the tooth bottom of the external teeth of the first rotor 11, and the projection 714 ' of the second side surface is tangent to the projection of the tooth bottom of the internal teeth of the second rotor 12, where "tangent" is a theoretical tangent, while there may be errors in the machining or assembling of parts in practice, and all the offsets within the machining errors and assembling errors are within the protection scope of the present invention; referring to fig. 8 and 9, the minimum distance between the outer peripheral edge of the first channel 10a and the first side 713 is 0.2mm or more, and the minimum distance between the outer peripheral edge of the first channel 10a and the second side 714 is 0.2mm or more; this enables the first channel 10a not to damage the first side 713 and the second side 714; in this embodiment, the first side surface 713 and the second side surface 714 are arc-shaped, and the minimum distance between the first side surface 713 and the second side surface 714 gradually decreases from the first head portion 711 to the first tail portion 712, in this embodiment, the first side surface 713 and the second side surface 714 are smooth surfaces, that is, no convex or concave structure features are provided on the first side surface 713 and the second side surface 714, and the "minimum distance between the first side surface 713 and the second side surface 714" refers to the minimum distance between the smooth surface of the first side surface 713 and the smooth surface of the second side surface 714; thus, when the oil pump is operated, the volume of the working medium stored in the first groove 71 gradually decreases from the first head 711 to the first tail 712, and the volume gradually decreases in the same manner as the volume change of the working medium in the second region 102, so that the working medium in the first groove 71 can flow out along with the working medium in the second region 102, thereby improving the pump efficiency.

Compared with the first embodiment of the oil pump, in this embodiment, the first housing 7 'is provided with the first groove 71, at least a part of the second region 102 is located in the first groove 71, the first passage 10a is provided in the first groove 71, and the first passage 10a penetrates through the bottom surface of the first groove 71' and the lower surface of the bottom wall 802a of the first accommodation portion; by arranging the first groove 71, part of working medium of the oil pump can be located in the first groove 71 in the working process, so that an oil film can be formed between the first rotor assembly and the bottom wall 802a, the friction force between the first rotor assembly and the bottom wall 802a in the rotating process can be reduced, and the noise caused by friction can be reduced; other features of the oil pump in this embodiment can refer to the first embodiment of the oil pump, and are not repeated herein.

The second passage in the first and second embodiments of the oil pump will be described in detail below; referring to fig. 12, the second channel 20 is disposed to penetrate through the first end surface 201 and the second end surface 202 of the pump shaft 20 along the axial direction of the pump shaft 3, in this embodiment, the cross section of the second channel 20 is a circular hole, and of course, the cross section of the second channel 20 may also be other shapes such as a square hole, or the second channel 20 may also communicate with the outer peripheral surface of the pump shaft 20, and at this time, the second channel 20 is equivalent to a radial opening along the pump shaft 3; specifically, in the present embodiment, the central axis of the second channel 20 coincides with the central axis of the pump shaft 3, where "coincidence" is theoretical coincidence, but actually, a coincidence error may exist in machining, and all offsets within the machining error are within the protection scope of the present invention; with reference to fig. 1, 7 and 10, the aperture of the first channel 10,10a is smaller than or equal to the aperture of the second channel 20, specifically, in this embodiment, the ratio of the aperture of the first channel 10,10a to the aperture of the second channel 20 is greater than or equal to 1/5 and smaller than or equal to 1, so that on one hand, the flow speed of the working medium in the second accommodating chamber 900 in the second channel 20 can be relatively reduced, which is beneficial to relatively prolonging the time for the stator assembly to perform heat exchange with the working medium, and is further beneficial to heat dissipation of the stator assembly, on the other hand, because the time for the stator assembly to perform heat exchange with the working medium is relatively prolonged, which is equivalent to prolonging the residence time of the working medium in the second accommodating chamber, and is therefore beneficial to relatively reducing the flow rate of the working medium entering the second accommodating chamber 900 in unit time, and is further beneficial to reducing the flow loss of the working medium in, thereby facilitating the improvement of pump efficiency. Referring again to fig. 1 and 7, the second passage 20 communicates the second receiving chamber 900 with the branch passage 64, and the branch passage 64 communicates with the outflow passage 62; in this embodiment, the outlet passage 62 and the branch passage 64 are located on the pump cover 6, and the outlet passage 62 and the branch passage 64 will be described in detail below.

Referring to fig. 13-17, fig. 13-17 are schematic structural views of a first embodiment of the pump cap of fig. 1 and 7, which will be described in detail below.

Referring to fig. 13 to 17, in the present embodiment, the inflow channel 61, the outflow channel 62, and the branch channel 64 are formed on the pump cover 6, specifically, the inflow channel 61 penetrates through the upper and lower end surfaces of the pump cover 6, the outflow channel 62 is recessed from the lower end surface 63 of the pump cover 6, and the outflow channel 62 does not penetrate through the upper end surface of the pump cover 6 along the axial direction of the pump cover 6; of course, it is also possible to not include the pump cover 6, but directly assemble other parts except the pump cover with the transmission case of the automobile, and at this time, the outflow channel 62 and the inflow channel 61 may be correspondingly formed on the transmission case; referring to fig. 15 and 17, the first region 101 is communicated with the inflow channel 61, the first region 101 is not communicated with the outflow channel 62, the second region 102 is not communicated with the inflow channel 61, the first rotor assembly 1, the inflow channel 61 and the outflow channel 62 are orthographically projected in a direction parallel to the upper end surface of the first rotor 11, a part of the projection of the first region 101 is located in the projection of the inflow channel 61, the projection of the first region 101 is not located in the projection of the outflow channel 62, and the projection of the second region 102 is located in the projection of the outflow channel 62; this is advantageous in preventing the working medium in the second region 102 from flowing to the first region 101 again, which is advantageous in reducing flow loss, and thus in improving pump efficiency.

Referring to fig. 15, the outflow channel 62 includes a first circulation portion 621 and a second circulation portion 622, the first circulation portion 621 and the second circulation portion 622 are communicated, the second circulation portion 622 is closer to the outer edge of the pump cover 6 than the first circulation portion 621, and the second circulation portion 622 penetrates through a part of the outer edge of the pump cover 6 in the radial direction of the pump cover 6; the first circulation part 621 is in smooth transition connection with the second circulation part 622, which is beneficial to smooth flow of the working medium; referring to fig. 16 and 17, the first flow-through 621 includes a first distal wall 6212 and a first proximal wall 6211, the first proximal wall 6211 being closer to the central axis of the first rotor 11 than the first distal wall 6212; referring to fig. 17, the first rotor assembly 1, the inflow channel 61 and the outflow channel 62 are orthographically projected in a direction parallel to the upper end surface of the first rotor, the projection of the second region 102 is located between the projection of the first proximal wall 6211 and the projection of the first distal wall 6212, specifically, the projection of the first proximal wall 6211 is tangent to the outer tooth bottom of the projection of the first rotor 11 or the projection of the first proximal wall 6211 is closer to the inner hole edge of the first rotor 11 than the outer tooth bottom of the projection of the first rotor 11, the projection of the first distal wall 6212 is tangent to the tooth bottom of the projection of the second rotor 12 or the first distal wall 6212 is closer to the outer edge of the second rotor 12 than the tooth bottom of the projection of the second rotor 12, where "tangent" is theoretical tangent, in fact, errors may exist in the processing or assembly of parts, and all offsets within the range of processing errors and assembly errors are within the protection range of the invention; the second area 102 is located in the first circulation part 621 in the above manner, so that on one hand, the working medium in the second area is prevented from flowing to the first area 101 through the first circulation part 621, and therefore, the outlet flow loss of the pump is reduced, and the pump efficiency is improved; on the other hand, a part of working medium in the second area 102 is extruded to the position with the minimum volume through the change of the volume and then flows out along the extending direction of the first circulation portion 621, and another part of working medium is not extruded to the position with the minimum volume and then is discharged, but directly flows into the first circulation portion through the corresponding volume cavity and then is discharged to the outlet of the oil pump, so that the outlet flow of the oil pump is favorably and relatively improved, and the pump efficiency is favorably improved.

Referring to fig. 15, the second flow-through portion 622 includes a second distal wall 6222 and a second proximal wall 6221, the second proximal wall 6221 is in smooth transition with the first proximal wall 6211, the second distal wall 6222 is in smooth transition with the first distal wall 6212, the outflow channel 62 and the first rotor assembly 1 are orthographically projected in a direction parallel to the upper end surface of the first rotor 11, the projection of the second proximal wall 6221 is not located in the first region 101, specifically, in the present embodiment, the projection of the second proximal wall 6221 coincides with the first dividing line L1, where "coincidence" is a theoretical coincidence, but there may be errors in the machining or assembly of parts, all offsets within the range of machining and assembly errors may be within the protection range of the present invention, the projection of the second proximal wall 6221 may not coincide with the first dividing line L1, and when the projection of the second proximal wall 6221 may pass through the first engaging point a or a point a near the first engaging point a, so long as the projection of the second proximal wall 6221 may not coincide with the first dividing line L, and the first outflow channel may facilitate the reduction of the leakage efficiency of the outflow channel 101, and the first outflow channel 101, and the leakage loss of the first outflow channel may be facilitated by the same working fluid, and the first outflow channel 621 being beneficial for the first outflow channel 621, and the same working fluid loss prevention of the same working fluid loss, in the same working fluid loss, and the first flow channel 621, and the same working fluid loss, as in the first flow channel 621.

Referring to fig. 15 and 16, in the present embodiment, the first proximal wall 6211 and the first distal wall 6212 are both arc-shaped, which facilitates the flow of the working medium; in addition, in the present embodiment, the first proximal wall 6211 is coaxially disposed with the first rotor 11, and the first distal wall 6212 is coaxially disposed with the second rotor 12, where "coaxial" is theoretical coaxial, but there may be errors in the machining or assembling of parts, and all coaxialities within the range of machining errors and assembling errors are within the protection scope of the present invention; referring to fig. 15, the first circulation portion 621 further includes a first front end portion 6213, and the vertical distance between the first proximal wall 6211 and the first distal wall 6212 gradually increases from the first front end portion 6213 to the transition connection between the first circulation portion 621 and the second circulation portion 622, which facilitates smooth flow of the working medium, on one hand, reduces noise, and on the other hand, reduces pressure loss of the working medium in the first circulation portion; referring to fig. 15 and 16, the second circulation portion 622 further includes a second rear end portion 6223, the second rear end portion 6223 is an open end of the second circulation portion 622 at the outer edge of the pump cap 6, the second rear end portion 6223 forms a part of an outlet of the oil pump, and a perpendicular distance between the second proximal wall 6221 and the second distal wall 6222 is constant from a transition connection between the first circulation portion 621 and the second circulation portion 622 to the second rear end portion 6223; specifically, referring to fig. 15 and 16, in the present embodiment, the second proximal wall 6221 is planar with the second distal wall 6222, the second proximal wall 6221 being disposed parallel to the second distal wall 6222; of course, the perpendicular distance between the second proximal wall 6221 and the second distal wall 6222 may also gradually increase from the transition connection between the first flow-through portion 621 and the second flow-through portion 622 to the second rear end portion 6223.

Referring to fig. 15 and 17, when the first rotor assembly 1, the inflow channel 61 and the outflow channel 62 are orthographically projected in a direction parallel to the upper end surface of the first rotor 11, the center of the projection of the first rotor 11 is a tangent Q1 of the projection of the first front end 6213, and an angle α between a tangent Q1 of the projection of the first front end and a second boundary L2 is greater than or equal to 8 ° and less than or equal to 19 °, on one hand, the first circulation portion 621 cannot be effectively communicated with the first region 101, and on the other hand, the communication area between the second region 102 and the first circulation portion 621 is favorably increased relatively, so that the working medium in the second region 102 can be favorably flowed out of the first circulation portion 62 as much as possible, and the outlet flow rate of the pump is favorably increased relatively, thereby favorably improving the pump efficiency.

Referring to fig. 15 and 16, the first front end portion 6213 includes a first upper end 6214 and a first lower end 6215, the first lower end 6215 being closer to the first rotor assembly 1 than the first upper end 6214 in the axial direction of the oil pump; along the extending direction of the outflow channel 62, the first upper end 6214 is closer to the second circulating part 622 than the first lower end 6215, the surface of the first front end 6213 is in an inclined plane shape, the first front end 6213 is inclined from the first upper end 6214 to the first lower end 6215, in this embodiment, the first lower end 6215 is formed on the lower end surface 63 of the pump cover 6, and the first upper end 6214 is formed on the bottom surface of the first circulating part 621; the inclined arrangement of the first front end portion 6213 is beneficial to guiding the working medium at the minimum volume chamber in the second region 102 into the first circulation portion 621, so that the working medium at the minimum volume chamber in the second region 102 can smoothly enter and exit the first circulation portion 621, and further, the generation of cavities can be reduced.

Referring to fig. 15 and 16, the pump cap 6 further includes a branch passage 64, the branch passage 64 is recessed from the lower end surface 63 of the pump cap 6, the branch passage 64 does not penetrate through the upper end surface of the pump cap along the axial direction of the pump cap 6, the inlet passage 61 is located on one side of the branch passage 64, the outlet passage 62 is located on the other side of the branch passage 64, and the branch passage 64 is located between the first proximal sidewall 6122 of the first flow-through portion 621 and the inlet passage 61; referring to fig. 1, 7, 15 and 16, one side of the branch channel 64 is communicated with the outflow channel 62, and the other side of the branch channel 64 is communicated with the second channel 20, so that the second channel 20 can be communicated with the outflow channel 62 through the branch channel 64, and the working medium in the second accommodating chamber 900 can flow into the outflow channel 62 through the second channel 20 and the branch channel 64 and then be discharged along the extending direction of the outflow channel 62, and this way of discharging the working medium in the second accommodating chamber 900 to the outflow channel 64 is beneficial to improving the outlet flow rate of the pump, and is further beneficial to improving the pump efficiency.

Referring to fig. 15 and 16, specifically, the branch passage 64 communicates with the first circulation portion 621; in this embodiment, the branch passage 64 includes a first communicating portion 641 and a second communicating portion 642, and the first communicating portion 641 directly communicates with the second passage 20; the second communicating portion 642 is provided penetrating the first proximal side wall 6211 and a part of the peripheral side wall of the first communicating portion 641 in the radial direction of the pump cover 6, so that the first communicating portion 641 communicates with the first communicating portion 621; referring to fig. 15 and 16, the cross-sectional flow area of the second communicating portion 642 is smaller than the cross-sectional flow area of the first communicating portion 641, or the aperture of the second communicating portion 642 is smaller than the aperture of the first communicating portion 641, which is advantageous for relatively reducing the flow speed of the working medium in the branch passage 64 flowing into the outflow passage 62, since the branch passage 64 is communicated with the second accommodating chamber 900 in fig. 1 or 7 through the second passage 20, the flow speed of the working medium in the second accommodating chamber 900 flowing into the second passage 20 is relatively reduced, and further, when the second accommodating chamber 900 is filled with the working medium, the flow speed of a part of the working medium in the first accommodating chamber 800 flowing into the second accommodating chamber 900 is relatively reduced, thereby being advantageous for prolonging the residence time of the working medium in the second accommodating chamber 900, and further being advantageous for relatively increasing the flow rate of the working medium flowing along the first flow direction in fig. 1 or 7 within a certain period of time, thereby being beneficial to improving the pump efficiency; referring to fig. 15, in the present embodiment, the second communicating portion 642 is disposed closer to the transition connection between the first communicating portion 621 and the second communicating portion 622 relative to the first front end portion 6213, and the pressure of the working medium near the first front end portion 6213 is greater than the pressure of the working medium near the transition connection between the first communicating portion 621 and the second communicating portion 622, and in combination with fig. 1, 7, 16 and 17, the projection 10 ', 10 a' of the first channel is closer to the first front end portion 6213 than the second communicating portion 642, so that the pressure of the working medium at the outlet of the second communicating portion 642 is less than the pressure of the working medium at the inlet of the first channel 10,10a, and thus the inlet of the first channel 10,10a and the outlet of the second communicating portion 642 can form a pressure difference, thereby facilitating the outflow of the working medium of the second accommodating chamber.

Referring to fig. 15, in the present embodiment, the recessed depth of the second communicating portion 642 is equal to that of the first communicating portion 641, that is, the bottom surface of the second communicating portion 642 is on the same plane as that of the first communicating portion 641, which is advantageous for smooth flow of the working medium in the branch passage; in addition, referring to fig. 15, in the present embodiment, the recessed depth of the branch passage 64 is smaller than that of the first flowing portion 621, which is beneficial to relatively reducing the working medium gathered in the branch passage 64 in a unit time, and since the branch passage 64 is communicated with the second accommodating chamber 900 in fig. 1 or 7 through the second passage 20, which is beneficial to relatively prolonging the time for the working medium in the second accommodating chamber 900 to gather in the branch passage 64, and is further beneficial to relatively prolonging the residence time of the working medium in the second accommodating chamber 900, so that the flow rate of a part of the working medium in the first accommodating chamber 800 into the second accommodating chamber 900 is relatively reduced, and is further beneficial to relatively increasing the flow rate of the working medium flowing along the first flowing direction in fig. 1 or 7 in a certain time, thereby being beneficial to relatively increasing the pump efficiency; of course, the recess depth of the branch passage 64 may be equal to the recess depth of the first flow-through portion 621.

Referring to fig. 15 to 17, orthographically projecting the second channel 20 toward the lower end surface 63 of the pump cover 6, the projection 20' of the second channel is located in the first communication portion 641, which is advantageous in that the working medium in the second channel 20 can sufficiently communicate with the first communication portion 641.

Referring to fig. 13 to 17, along the axial direction of the pump cover 6, the intake passage 61 penetrates the upper and lower end surfaces of the pump cover 6; the inlet channel 61 comprises a third proximal wall 611 and a third distal wall 612, the third proximal wall 611 being closer to the central axis of the first rotor than the third distal wall 612, see fig. 17, orthographically projecting the first rotor assembly 1 and the inlet channel 61 in a direction parallel to the upper end face of the first rotor, the projection of the third distal wall 612 being tangent to the tooth bottoms of the projected inner teeth of the second rotor 12, the third proximal wall 611 being tangent to the tooth bottoms of the projected inner teeth of the first rotor 11, where "tangent" is theoretical tangent, and there may be errors in the actual machining or assembly of the parts, all deviations within the range of machining errors and assembly errors are within the scope of the present invention, of course, the projection of the third far-side wall 612 may be closer to the outer edge of the second rotor 12 than the tooth bottom of the projected inner teeth of the second rotor 12, and the projection of the third near-side wall 611 may be closer to the inner hole edge of the first rotor 11 than the tooth bottom of the projected inner teeth of the first rotor 11; thus, at least part of the projection of the first region 101 is located in the projection of the inflow channel 61, and two boundaries of the projection of the first region 101 do not cross the projection of the third near-side wall 611 and the projection of the third far-side wall 612, so that the working medium in the inflow channel 61 can effectively flow into the first region 101, and further the pump efficiency is further improved.

Referring to fig. 16 and 17, the flow passage 61 further includes a third front end portion 613 and a third rear end portion 614, the third front end portion 613 is closer to the first front end portion 6213 of the first flow passage than the third rear end portion 614, and a perpendicular distance between the third proximal wall 611 and the third distal wall 612 gradually increases from the third front end portion 613 to the third rear end portion 614; in this way, the volume change process of the inflow channel 61 is the same as the volume change process of the working medium in the first region 101 in the rotation direction of the first rotor assembly, which facilitates a relative increase in the flow rate of the working medium into the first region per unit time when the working medium enters the first region through the inflow channel 61, thereby facilitating an increase in the pump efficiency.

Referring to fig. 13 and 14, the third front end 613 further includes a second upper end 6131 and a second lower end 6132, the second upper end 6131 is formed on the upper end face of the pump cover, and the second lower end 6132 is formed on the lower end face of the pump cover; along the circumferential direction of the pump cover 6, the second lower end 6132 is closer to the third rear end 614 than the second upper end 6131, and the surface of the third front end 613 is inclined; referring to fig. 14 and 17 in combination, the inclined arrangement of the second front end 613 facilitates guiding the working medium in the flow inlet channel 61 into the first region 101, so as to facilitate smooth flow of the working medium from the flow inlet channel 61 into the first region 101, and further facilitate reducing the generation of voids.

Referring to fig. 18-19, and 18-19, which are schematic structural views of a second embodiment of the pump cap of fig. 1 or 7, the second embodiment of the pump cap will be described in detail below.

Referring to fig. 18 to 19, in the present embodiment, the outflow channel 62 ' further includes a third flow portion 623 ', the third flow portion 623 ' is directly communicated with the second flow portion 622 ', and the third flow portion 623 ' penetrates through a part of the outer edge of the pump cover 6 along the radial direction of the pump cover 6; referring to fig. 19, to facilitate description of the third flow-through portion 623 ', a dividing surface is introduced, the second proximal wall 6221 ' is located within the dividing surface K, the dividing surface K is parallel to the second proximal wall 6221 ', the second flow-through portion 622 ' is located on one side of the dividing surface K, the third flow-through portion 623 ' is located on the other side of the dividing surface K, the third flow-through portion 623 ' includes a fourth proximal wall 6231 ' and a fifth proximal wall 6232 ', the fourth proximal wall 6231 ' is in smooth transition with the second proximal wall 6221 ', the fifth proximal wall 6232 ' is in smooth transition with the fourth proximal wall 6231 ', and the fifth proximal wall 6232 ' is connected with the outer edge of the pump cap; in this embodiment, the third flow portion 623' is provided, so that the oil pump can meet the requirement of a relatively large-caliber interface.

Compared with the first embodiment of the pump cover, in the embodiment, the pump cover further comprises a third circulation part 623 ', and the oil pump can meet the interface requirement of relatively large caliber by arranging the third circulation part 623'; other features of the pump cover in this embodiment can refer to the first embodiment of the pump cover, and are not repeated herein.

It should be noted that: the above embodiments are only used for illustrating the present invention and not for limiting the technical solutions described in the present invention, and although the present invention has been described in detail with reference to the above embodiments, it should be understood by those skilled in the art that the technical solutions and modifications thereof without departing from the spirit and scope of the present invention can be modified or replaced by other technical solutions and modifications by those skilled in the art.

Claims (16)

1. An oil pump comprises a first rotor assembly, a stator assembly, a second rotor assembly, a first accommodating part and a second accommodating part, wherein the first accommodating part is provided with a first accommodating cavity, the second accommodating part is provided with a second accommodating cavity, the first rotor assembly is arranged in the first accommodating cavity, and the stator assembly and the second rotor assembly are arranged in the second accommodating cavity; the oil pump comprises an inflow channel and an outflow channel, the inflow channel is used for inflow of working media, the outflow channel is used for outflow of the working media, and the inflow channel and the outflow channel are located above the first rotor assembly; the method is characterized in that: the first rotor assembly comprises a first rotor and a second rotor, the first rotor is provided with a plurality of external teeth, the second rotor is provided with a plurality of internal teeth, the second rotor is positioned on the outer periphery of the first rotor, and transmission between the first rotor and the second rotor is enabled through meshing of at least part of the external teeth of the first rotor and at least part of the internal teeth of the second rotor;

a volume cavity is arranged between the outer teeth of the first rotor and the inner teeth of the second rotor; the volume chamber is divided into a first region in which a volume chamber formed between one outer tooth of the first rotor and an inner tooth of the second rotor corresponding to the outer tooth is gradually increased in volume in a rotation direction of the first rotor assembly, and a second region in which a volume chamber formed between one outer tooth of the first rotor and an inner tooth of the second rotor corresponding to the outer tooth is gradually decreased in volume in the rotation direction of the first rotor assembly; orthographically projecting the first rotor assembly toward an upper end face parallel to the first rotor, in the projection of the first rotor assembly, defining a first boundary line at which one outer tooth of the first rotor meshes with one inner tooth of the second rotor to form a first meshing point, the first boundary line being a line connecting the first meshing point with a center of the first rotor, the first boundary line being a dividing line at which the first region ends and the second region starts;

the first area is communicated with the inflow channel, the first area is not communicated with the outflow channel, the second area is communicated with the outflow channel, and the second area is not communicated with the inflow channel; orthographically projecting the first rotor assembly, the inflow channel and the outflow channel to a direction parallel to the upper end face of the first rotor, wherein a projection of a part of the first area is located in a projection of the inflow channel, a projection of the first area is not located in a projection of the outflow channel, and a projection of the second area is located in a projection of the outflow channel.

2. The oil pump of claim 1, wherein: the outflow channel comprises a first circulation part and a second circulation part, the first circulation part is in smooth transition connection with the second circulation part, the second circulation part is closer to an outlet of the oil pump than the first circulation part, and the first circulation part is communicated with the second circulation part; the first flow-through portion includes a first distal wall and a first proximal wall that is closer to a central axis of the first rotor than the first distal wall; and projecting the first rotor assembly and the first circulation part to the direction parallel to the upper end face of the first rotor in an orthographic mode, wherein the projection of the first near-side wall is tangent to the tooth bottom of the outer teeth projected by the first rotor or the projection of the first near-side wall is closer to the inner hole edge of the first rotor than the tooth bottom of the inner teeth projected by the first rotor, and the projection of the first far-side wall is tangent to the tooth bottom of the inner teeth of the second rotor or the projection of the first far-side wall is closer to the outer edge of the second rotor than the tooth bottom of the inner teeth of the second rotor.

3. The oil pump of claim 2, wherein: the first near side wall and the first far side wall are arc-surface-shaped, the first near side wall is coaxially arranged with the first rotor, and the first far side wall is coaxially arranged with the second rotor; the first flow-through further includes a first leading end portion, a perpendicular distance between the first proximal wall and the first distal wall gradually increasing from the first leading end portion to a transition junction between the first flow-through and the second flow-through.

4. The oil pump of claim 3, wherein: the second flow-through portion comprises a second distal wall and a second proximal wall, the second proximal wall being in smooth-transitioning connection with the first proximal wall, the second distal wall being in smooth-transitioning connection with the first distal wall; orthographically projecting the outflow channel and the first rotor assembly to a direction parallel to an upper end surface of the first rotor, a projection of the second proximal wall not being located within the first region; the second circulation portion further comprises a second rear end portion, the second rear end portion is an open end of the second circulation portion, and a perpendicular distance between the second proximal wall and the second distal wall is gradually increased or unchanged from a transition connection portion between the first circulation portion and the second circulation portion to the second rear end portion.

5. The oil pump of claim 4, wherein: the bottom surface of the first circulation part and the bottom surface of the second circulation part are on the same plane; the second proximal wall and the second distal wall are planar, and the second proximal wall and the second distal wall are arranged in parallel.

6. The oil pump according to any one of claims 3 to 5, characterized in that: defining a second boundary line at which the other external teeth of the first rotor mesh with the other internal teeth of the second rotor to form a second meshing point, the second boundary line being a line connecting the second meshing point with the center of the first rotor, the second boundary line serving as a dividing line between the start of the first region and the end of the second region; orthographically projecting the first rotor assembly and the outflow channel to a direction parallel to the upper end face of the first rotor, making a tangent of the first front end projection passing through the center of the first rotor projection, wherein an angle between the tangent of the first front end projection and the second boundary line is greater than or equal to 8 degrees and smaller than or equal to 19 degrees.

7. The oil pump of claim 6, wherein: the first front end portion includes a first upper end formed at a bottom surface of the first flow-through portion, and a first lower end closer to the first rotor assembly than the first upper end in an axial direction of the oil pump; along the extending direction of the outflow passage, the first upper end is closer to the second flow-through portion than the first lower end, and a surface of the first front end portion is in an inclined surface shape.

8. The oil pump of claim 1, 2, 3, 4, 5, or 7, wherein: the inlet channel includes a third proximal wall and a third distal wall, the third proximal wall being closer to the central axis of the first rotor than the third distal wall; and projecting the first rotor assembly and the inflow channel to the direction parallel to the upper end face of the first rotor in an orthographic mode, wherein the projection of the third far side wall is tangent to the tooth bottom of the inner teeth projected by the second rotor or the projection of the third far side wall is closer to the outer edge of the second rotor than the tooth bottom of the inner teeth projected by the second rotor, and the projection of the third near side wall is tangent to the tooth bottom of the inner teeth projected by the first rotor or the projection of the third near side wall is closer to the inner hole edge of the first rotor than the tooth bottom of the inner teeth projected by the first rotor.

9. The oil pump of claim 6, wherein: the inlet channel includes a third proximal wall and a third distal wall, the third proximal wall being closer to the central axis of the first rotor than the third distal wall; and projecting the first rotor assembly and the inflow channel to the direction parallel to the upper end face of the first rotor in an orthographic mode, wherein the projection of the third far side wall is tangent to the tooth bottom of the inner teeth projected by the second rotor or the projection of the third far side wall is closer to the outer edge of the second rotor than the tooth bottom of the inner teeth projected by the second rotor, and the projection of the third near side wall is tangent to the tooth bottom of the inner teeth projected by the first rotor or the projection of the third near side wall is closer to the inner hole edge of the first rotor than the tooth bottom of the inner teeth projected by the first rotor.

10. The oil pump of claim 8, wherein: the inlet passage further includes a third front end portion and a third rear end portion, the inlet passage and the first rotor assembly are orthographically projected parallel to the upper end surface of the first rotor, the projection of the third front end portion is closer to the start of the second region than the projection of the third rear end portion, and the minimum distance between the third proximal wall and the third distal wall gradually increases from the third front end portion to the third rear end portion.

11. The oil pump of claim 9, wherein: the inlet passage further includes a third front end portion and a third rear end portion, the inlet passage and the first rotor assembly are orthographically projected parallel to the upper end surface of the first rotor, the projection of the third front end portion is closer to the start of the second region than the projection of the third rear end portion, and the minimum distance between the third proximal wall and the third distal wall gradually increases from the third front end portion to the third rear end portion.

12. The oil pump according to claim 10 or 11, characterized in that: the oil pump also comprises a first channel, the first channel penetrates through the upper surface and the lower surface of the bottom wall of the first accommodating part, the first channel can be communicated with the first accommodating cavity and the second accommodating cavity, a working medium can flow in the first accommodating cavity, and part of the working medium in the first accommodating cavity can flow into the second accommodating cavity through the first channel and is in contact with at least part of the stator assembly in the second accommodating cavity; the oil pump further comprises a second channel and a pump shaft, the second channel is arranged to penetrate through a first end face of the pump shaft and a second end face of the pump shaft, and working media in the second accommodating cavity can leave the second accommodating cavity through the second channel; the outlet of the second channel is closer to the inflow channel than the inlet of the first channel, and the pressure of the working medium at the outlet of the second channel is lower than the pressure of the working medium at the inlet of the first channel; the oil pump further includes a branch passage through which the second passage communicates with the outflow passage.

13. The oil pump of claim 12, wherein: the branch passage comprises a first communicating part and a second communicating part, the first communicating part is communicated with the second passage, and the second communicating part is communicated with the first communicating part; orthographically projecting the second channel to the branch channel, the projection of the second channel being located in the first communicating portion; the first communicating portion includes a first proximal wall, and the second communicating portion is provided so as to penetrate the first proximal wall and a partial peripheral wall of the first communicating portion.

14. The oil pump of claim 13, wherein: the outflow channel comprises a first flowing part and a second flowing part, the second flowing part is arranged closer to the transition joint of the first flowing part and the second flowing part relative to the first front end part, and the depression depth of the branch channel is less than or equal to that of the first flowing part; a flow cross-sectional area of the second communicating portion is smaller than a flow cross-sectional area of the first communicating portion, and a recessed depth of the second communicating portion is equal to a recessed depth of the first communicating portion; the second communicating portion is closer to a transition connection between the first communicating portion and the second communicating portion than to the first front end portion of the first communicating portion.

15. The oil pump of claim 12, wherein: the oil pump also comprises a pump cover, and the pump cover is positioned above the first rotor assembly; the pump cover is provided with the inflow channel, the outflow channel and the branch channel, the inflow channel penetrates through the upper end surface and the lower end surface of the pump cover, the outflow channel is arranged from the lower end surface of the pump cover in a concave mode, and the outflow channel does not penetrate through the upper end surface of the pump cover along the axial direction of the pump cover; the branch passage is arranged from the lower end face of the pump cover in a recessed mode, the branch passage does not penetrate through the upper end face of the pump cover along the axial direction of the pump cover, the inflow passage is located on one side of the branch passage, and the outflow passage is located on the other side of the branch passage.

16. The oil pump of claim 13 or 14, wherein: the oil pump also comprises a pump cover, and the pump cover is positioned above the first rotor assembly; the pump cover is provided with the inflow channel, the outflow channel and the branch channel, the inflow channel penetrates through the upper end surface and the lower end surface of the pump cover, the outflow channel is arranged from the lower end surface of the pump cover in a concave mode, and the outflow channel does not penetrate through the upper end surface of the pump cover along the axial direction of the pump cover; the branch passage is arranged from the lower end face of the pump cover in a recessed mode, the branch passage does not penetrate through the upper end face of the pump cover along the axial direction of the pump cover, the inflow passage is located on one side of the branch passage, and the outflow passage is located on the other side of the branch passage.

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