FUEL PUMP
A fuel pump includes a pump part, a motor part, a motor casing, a motor cover, a terminal, and an electric connector part. The terminal is electrically connectable to an external connector for electricity supply. The electric connector part is disposed at an end portion of the motor cover located on the opposite side from a fitted end of the motor cover which is fitted with a housing, and includes a side surface which is slidably in contact with the external connector to determine a fitting position of the electric connector part relative to the external connector, a bottom face from which the terminal rises up, and an opening which is formed on the side surface to communicate between inside and outside of the electric connector part. The bottom face is an inclined surface whose height becomes lower in a direction from generally a center of the motor cover toward the opening.
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This application is based on and incorporates herein by reference Japanese Patent Application No. 2010-194456 filed on Aug. 31, 2010.
BACKGROUND OF THE INVENTION1. Field of the Invention
The present invention relates to a fuel pump that drives its pump part by driving force of its motor part to suction and pressurize fuel.
2. Description of Related Art
A fuel pump that supplies fuel to an internal combustion engine is known. The fuel pump pressurizes fuel suctioned from a fuel tank by its pump part, and supplies the fuel to the engine. In the fuel pump, an electric current supplied via its electric connector part flows through a coil, so that a rotor, around which the coil is wound, rotates to drive the pump part. In JP-A-2008-243569, by changing a shape of a resin member that supports a terminal of an electric connector part, a corrosion or short circuit of the terminal which is caused due to the residue of fuel inside the electric connector part is prevented.
In the electrical connector described in JP-A-2008-243569, an opening for discharging the fuel that remains in the electric connector part into the outside is provided on a side surface of the electric connector part. However, if fuel remains away from the opening, or if the residual fuel becomes high-viscosity liquid as a result of the evaporation of its volatile matter content, the discharge of fuel from the opening becomes difficult, and they remain inside the electric connector part. Particularly, because the liquid, whose impure substance has been condensed due to the evaporation of volatile matter content, exhibits high conductivity, the terminal corrodes by a leak current between both poles, and eventually damage of the terminal is caused.
SUMMARY OF THE INVENTIONThe present invention addresses at least one of the above disadvantages.
According to the present invention, there is provided a fuel pump including a pump part, a motor part, a motor casing, a motor cover, a terminal, and an electric connector part. The pump part includes a rotation member configured to suction and pressurize fuel. The motor part includes a rotor coupled with a rotating shaft of the rotation member to be capable of rotating the rotation member, a commutator rotated together with the rotor to rectify an electric current supplied to the rotor, and a housing accommodating the rotor and the commutator. The motor casing supports one end of the rotating shaft of the rotation member. The motor cover is disposed at one end of the motor part in an axial direction thereof and is fitted together with the housing so as to fix the motor casing. The terminal is disposed at an end portion of the motor cover located on an opposite side from a fitted end of the motor cover, which is fitted with the housing. The terminal is electrically connectable to an external connector for electricity supply. The electric connector part is disposed at the end portion of the motor cover located on the opposite side from the fitted end of the motor cover, and includes a side surface which is slidably in contact with the external connector to determine a fitting position of the electric connector part relative to the external connector, a bottom face from which the terminal rises up, and an opening which is formed on the side surface to communicate between inside and outside of the electric connector part. The bottom face is an inclined surface whose height becomes lower in a direction from generally a center of the motor cover toward the opening.
According to the present invention, there is also provided a fuel pump including a pump part, a motor part, a motor casing, a motor cover, a terminal, and an electric connector part. The pump part includes a rotation member configured to suction and pressurize fuel. The motor part includes a rotor coupled with a rotating shaft of the rotation member to be capable of rotating the rotation member, a commutator rotated together with the rotor to rectify an electric current supplied to the rotor, and a housing accommodating the rotor and the commutator. The motor casing supports one end of the rotating shaft of the rotation member. The motor cover is disposed at one end of the motor part in an axial direction thereof and is fitted together with the housing so as to fix the motor casing. The terminal is disposed at an end portion of the motor cover located on an opposite side from a fitted end of the motor cover, which is fitted with the housing. The terminal is electrically connectable to an external connector for electricity supply. The electric connector part is disposed at the end portion of the motor cover located on the opposite side from the fitted end of the motor cover, and includes a side surface which is slidably in contact with the external connector to determine a fitting position of the electric connector part relative to the external connector, a bottom face from which the terminal rises up, and an opening which is formed on the side surface to communicate between inside and outside of the electric connector part. The bottom face includes a groove in a direction from generally a center of the motor cover toward the opening, the groove connecting to the opening.
The invention, together with additional objectives, features and advantages thereof, will be best understood from the following description, the appended claims and the accompanying drawings in which:
Embodiments of the invention will be described below with reference to the accompanying drawings.
First EmbodimentA fuel pump 10 of a first embodiment of the invention is illustrated in
The pump part 12 includes a casing main body 31, a casing cover 32, and an impeller 33 which is a rotation member. The casing main body 31 and the casing cover 32 define a generally C-shaped pump passage 34. The impeller 33 is accommodated rotatably between the casing main body 31 and the casing cover 32. The casing main body 31 and the casing cover 32 are formed by, for example, die casting of aluminum.
The casing main body 31 is fixed in one end side of the housing 16 in an axial direction thereof by press fitting. A pump part side bearing 35 that rotatably supports a shaft 21, which is connected to the impeller 33, is disposed at a central part of the casing main body 31.
The casing cover 32 is fixed to one end portion of the housing 16 by calking, with the casing main body 31 covered in the cover 32. A thrust bearing 36 that limits axial displacement of the shaft 21 is fixed at a central part of the casing cover 32. The casing cover 32 has a fuel inlet 38.
A motor casing 41 and a motor cover 42 are disposed at the other end portion of the housing 16, i.e., on the opposite side of the housing 16 from the casing main body 31 and the casing cover 32. The motor casing 41 is located between the motor cover 42 and the housing 16. The motor casing 41 includes a connecting passage 44 that connects together a pump chamber 22 and a fuel passage 43 of the motor cover 42. The motor casing 41 defines a brush accommodating chamber 45 which accommodates a brush 70 such that the brush 70 can be reciprocated in its axial direction, as illustrated in
As illustrated in
Terminals 60, 61 are provided for the electric connector part 50, which is connected to the outside of the fuel pump 10. As illustrated in
As illustrated in
The electric connector part 50 will be described in detail. The electric connector part 50 is provided on the opposite side of the center of the motor cover 42 from the fuel discharge part 46 as illustrated in
As illustrated in
The communication parts 53, 55 are formed at both ends of the terminal part 51 in a tangential direction of the motor cover 42 to be connected to the terminal part 51. As illustrated in
As illustrated in
Operation of the fuel pump 10 of the first embodiment will be described. An electric current supplied to the terminal 60 from a power source (not shown) is fed to the commutator 80 through the brush terminal 73, the pigtail 71, and the brush 70. The electric current fed into the commutator 80 is supplied to the coil 23 of the rotor 20. Upon rotation of the rotor 20 by the electric current supplied to the coil 23, the impeller 33 rotates together with the rotor 20 and the shaft 21. When the impeller 33 rotates, fuel is suctioned into the pump passage 34 through the fuel inlet 38. The fuel suctioned into the pump passage 34 is discharged from the pump passage 34 into the pump chamber 22 as a result of application of kinetic energy to the fuel by vane grooves of the impeller 33. The fuel discharged into the pump chamber 22 is supplied to the outside of the fuel pump 10 through a surrounding area of the rotor 20 and the fuel passage 43.
As a result of the increase of fuel in the fuel tank in the electric connector part 50 with its opening 57 for the external connector formed upward, a part of fuel enters into the electric connector part 50. On the other hand, when a fluid level of fuel decreases as a result of the consumption of fuel, the fuel, which has entered into the electric connector part 50, moves from higher bottom faces toward lower bottom faces along the communication part bottom faces 54, 56 connected to the openings 58, 59, so as to be discharged into the outside of the electric connector part 50.
Generally, fuel remains in an electric connector part due to increase and decrease of fuel in a fuel tank. The residual fuel becomes liquid containing many involatile impure substances as a result of evaporation of its volatile matter content. The liquid including many impure substances does not easily move inside the electric connector part because of its high viscosity. Accordingly, the liquid is not easily discharged even if there is an opening for discharging the fuel, which has entered into the electric connector part, into the outside.
In the fuel pump 10 of the first embodiment of the invention, the communication part bottom faces 54, 56, whose heights become lower outward in a radial direction of the motor cover 42, are provided for the electric connector part 50. The liquid including many impure substances that has remained inside the electric connector part 50 moves toward the openings 58, 59 along the inclined surfaces of the communication part bottom faces 54, 56 by the action of gravity. Then, the liquid is discharged into the outside of the electric connector part 50 through the openings 58, 59. Accordingly, adhesion of impure substances contained in the residual liquid to the terminals 60, 61 can be prevented. As a result, development of corrosion of the terminals 60, 61, and eventually damage to the terminals 60, 61 can be prevented.
Second EmbodimentA second embodiment of the invention will be described with reference to
Openings 68, 69 are connected to the V—shapes, which are constituted of the communication part center side bottom faces 641, 661 and the communication part outer side bottom faces 642, 662. Specifically, as illustrated in
In the second embodiment, liquid that remains in the electric connector part 50 is collected at the recessed ridgelines 643, 663 along the inclined surfaces of the communication part center side bottom faces 641, 661 and the communication part outer side bottom faces 642, 662. After that, the collected liquid is discharged into the outside of the electric connector part 50 through the openings 68, 69. Since the fuel that remains inside the electric connector part 50 is gathered temporarily around the recessed ridgelines 643, 663, even if the amount of remaining liquid is small as compared with the first embodiment, the liquid is easily discharged into the outside of the electric connector part 50.
Modifications of the above embodiments will be described. Firstly, in the above first embodiment, the shape of the communication part bottom face is a planar inclined surface toward the opening. Alternatively, the shape of the communication part bottom face is not limited to this. The shape of the communication part bottom face may be a curved surface having a conical shape, a hemispherical shape, a radial shape, or the like; and a gradient ratio of its inclination may be changed within this surface.
Secondly, in the above second embodiment, a groove formed on the communication part bottom face is V-shaped at a generally central position of the communication part bottom face. However, the arrangement position of the groove, the shape of the groove, the number of grooves, and height of a recessed ridgeline of the groove are not necessarily limited to this.
Thirdly, in the above second embodiment, only the groove is formed on the communication part bottom face. Alternatively, what is formed on the communication part bottom face is not exclusive to the groove. A communication part bottom face, on which the groove is combined with the inclined surface described in the above first embodiment, may be employed.
Fourthly, in the above embodiments, the inclined surface or the groove is formed on the communication part bottom face. However, a surface, on which the inclined surface or the groove is formed, is not limited to the communication part bottom face. The inclined surface or the groove may be formed also on the terminal part bottom face, through which the terminal is disposed.
Fifthly, in the above embodiments, the height of the communication part bottom face and the height of the lower end of the opening are set to be the same. Alternatively, a positional relationship between the communication part bottom face and the opening is not necessarily limited to this. Any positional relationship may be employed as long as the height of the communication part bottom face is equal to or higher than the height of the lower end of the opening.
Sixthly, in the above embodiments, the shape of the opening is generally rectangular or generally pentagonal. However, the shape of the opening is not limited to this. The shape of the opening may be a shape that conforms with the shape of the communication part bottom face, such as a generally round shape or a generally polygon.
Lastly, in the above embodiments, the example of application of the impeller having vane grooves to the rotation member of the pump part is described. However, instead of the application of the impeller, another type of a pump, such as a Trochoid (registered trademark) pump or a gear pump, may be applied to the rotation member.
The embodiments of application of the invention to the in-tank pump disposed inside the fuel tank of the vehicle have been described above. Nevertheless, the invention is not by any means limited to such embodiments, and may be embodied in various modes without departing from the scope of the invention.
To sum up, the fuel pump 10 of the above embodiments may be described as follows.
The fuel pump 10 includes a pump part 12, a motor part 14, a motor casing 41, a motor cover 42, a terminal 60 or 61, and an electric connector part 50. The pump part 12 includes a rotation member 33 configured to suction and pressurize fuel. The motor part 14 includes a rotor 20 coupled with a rotating shaft 21 of the rotation member 33 to be capable of rotating the rotation member 33, a commutator 80 rotated together with the rotor 20 to rectify an electric current supplied to the rotor 20, and a housing 16 accommodating the rotor 20 and the commutator 80. The motor casing 41 supports one end of the rotating shaft 21 of the rotation member 33. The motor cover 42 is disposed at one end of the motor part 14 in an axial direction thereof and is fitted together with the housing 16 so as to fix the motor casing 41. The terminal 60 or 61 is disposed at an end portion of the motor cover 42 located on an opposite side from a fitted end of the motor cover 42, which is fitted with the housing 16. The terminal 60 or 61 is electrically connectable to an external connector for electricity supply. The electric connector part 50 is disposed at the end portion of the motor cover 42 located on the opposite side from the fitted end of the motor cover 42, and includes a side surface 501, 502, 503, or 504 which is slidably in contact with the external connector to determine a fitting position of the electric connector part 50 relative to the external connector, a bottom face 54 or 56; 64 or 66 from which the terminal 60 or 61 rises up, and an opening 58 or 59; 68 or 69 which is formed on the side surface 501, 502, 503, or 504 to communicate between inside and outside of the electric connector part 50. The bottom face 54 or 56; 64 or 66 is an inclined surface whose height becomes lower in a direction from generally a center of the motor cover 42 toward the opening 58 or 59; 68 or 69.
The bottom faces 54, 56 of the electric connector part 50 are inclined surfaces whose heights becomes lower from the generally center of the motor cover 42 toward the openings 58, 59. The liquid that remains inside the electric connector part 50 moves toward the openings 58, 59 having lower heights along the inclined surfaces formed on the bottom faces 54, 56 of the electric connector part 50. Then, the liquid is discharged from the openings 58, 59 into the outside of the electric connector part 50. Accordingly, corrosion of the terminals 60, 61 caused by adhesion of impure substances contained in the residual liquid can be prevented.
A gradient ratio of an inclination of the inclined surface may change within the inclined surface. Specifically, the bottom faces 54, 56 of the electric connector part 50 are not the inclined surfaces having a certain gradient ratio in the whole regions thereof. Alternatively, an arbitrary gradient ratio may be set at an arbitrary position on each of the bottom faces 54, 56 of the electric connector part 50. Consequently, by forming the inclined surfaces 54, 56 having large gradient ratios at the positions at which the liquid is more likely to remain, the residual liquid easily moves to be collected. As a result, the corrosion of the terminals 60, 61 due to attachments contained in the remaining liquid can be prevented.
The bottom face 64 or 66 may include a groove in the direction from generally the center of the motor cover 42 toward the opening 68 or 69. The groove may connect to the opening 68 or 69. By the formation of grooves on the bottom faces 64, 66 of the electric connector part 50 from the generally center of the motor cover 42 toward the openings 68, 69, the liquid that remains inside the electric connector part 50 can be collected at the lowest portions 643, 663 of the grooves. After that, the liquid collected at the lowest portions 643, 663 of the grooves is discharged into the outside through their connecting openings 68, 69. Accordingly, even if the amount of liquid remaining inside the electric connector part 50 is small, the liquid is easily removed, and corrosion of the terminals 60, 61 can be prevented.
A height of a recessed ridgeline 643 or 663 of the groove may become lower in the direction from generally the center of the motor cover 42 toward the opening 68 or 69. Consequently, the liquid gathered at the recessed ridgelines 643, 663 of the grooves moves toward the openings 68, 69 having lower heights, and is discharged into the outside of the electric connector part 50. As a result, the residual liquid can be efficiently discharged as compared with the grooves whose recessed ridgelines 643, 663 have constant heights.
Additional advantages and modifications will readily occur to those skilled in the art. The invention in its broader terms is therefore not limited to the specific details, representative apparatus, and illustrative examples shown and described.
Claims
1. A fuel pump comprising:
- a pump part that includes a rotation member configured to suction and pressurize fuel;
- a motor part that includes: a rotor coupled with a rotating shaft of the rotation member to be capable of rotating the rotation member; a commutator rotated together with the rotor to rectify an electric current supplied to the rotor; and a housing accommodating the rotor and the commutator;
- a motor casing that supports one end of the rotating shaft of the rotation member;
- a motor cover that is disposed at one end of the motor part in an axial direction thereof and is fitted together with the housing so as to fix the motor casing;
- a terminal that is disposed at an end portion of the motor cover located on an opposite side from a fitted end of the motor cover, which is fitted with the housing, the terminal being electrically connectable to an external connector for electricity supply; and
- an electric connector part that is disposed at the end portion of the motor cover located on the opposite side from the fitted end of the motor cover and that includes: a side surface which is slidably in contact with the external connector to determine a fitting position of the electric connector part relative to the external connector; a bottom face from which the terminal rises up; and an opening which is formed on the side surface to communicate between inside and outside of the electric connector part, wherein the bottom face is an inclined surface whose height becomes lower in a direction from generally a center of the motor cover toward the opening.
2. The fuel pump according to claim 1, wherein a gradient ratio of an inclination of the inclined surface changes within the inclined surface.
3. The fuel pump according to claim 1, wherein the bottom face includes a groove in the direction from generally the center of the motor cover toward the opening, the groove connecting to the opening.
4. The fuel pump according to claim 3, wherein a height of a recessed ridgeline of the groove becomes lower in the direction from generally the center of the motor cover toward the opening.
5. A fuel pump comprising:
- a pump part that includes a rotation member configured to suction and pressurize fuel;
- a motor part that includes: a rotor coupled with a rotating shaft of the rotation member to be capable of rotating the rotation member; a commutator rotated together with the rotor to rectify an electric current supplied to the rotor; and a housing accommodating the rotor and the commutator;
- a motor casing that supports one end of the rotating shaft of the rotation member;
- a motor cover that is disposed at one end of the motor part in an axial direction thereof and is fitted together with the housing so as to fix the motor casing;
- a terminal that is disposed at an end portion of the motor cover located on an opposite side from a fitted end of the motor cover, which is fitted with the housing, the terminal being electrically connectable to an external connector for electricity supply; and
- an electric connector part that is disposed at the end portion of the motor cover located on the opposite side from the fitted end of the motor cover and that includes: a side surface which is slidly in contact with the external connector to determine a fitting position of the electric connector part relative to the external connector; a bottom face from which the terminal rises up; and an opening which is formed on the side surface to communicate between inside and outside of the electric connector part, wherein the bottom face includes a groove in a direction from generally a center of the motor cover toward the opening, the groove connecting to the opening.
6. The fuel pump according to claim 5, wherein a height of a recessed ridgeline of the groove becomes lower in the direction from generally the center of the motor cover toward the opening.
Type: Application
Filed: Aug 11, 2011
Publication Date: Mar 1, 2012
Applicant: DENSO CORPORATION (Kariya-city)
Inventors: Rihito ASAI (Kariya-city), Yoshitaka Wakamatsu (Gamagori-city), Hideki Koyama (Okazaki-city), Motoya Ito (Hekinan-city), Toshitake Yaura (Chiryu-city)
Application Number: 13/207,710
International Classification: F04B 35/04 (20060101);