JP6027768B2 - Multistage oil pump - Google Patents

Description

  The present invention relates to a multistage oil pump particularly used for automobiles and the like.

  Conventionally, a multistage oil pump in which a plurality of rotors are connected in series has been provided (for example, Patent Document 1). As shown in FIG. 1, the trochoid pumps (rotors) 4 and 5 are directly housed in a bottomed cylindrical housing body 1.

JP 2006-161614 A

  However, the above structure has a problem that it is heavy because it is an iron-based material.

  An object of this invention is to provide the multistage oil pump which can solve the said subject.

To solve such problems, a multi-stage oil pump of the present invention is a multi-stage oil pump in which a plurality of rotors are connected in series, it is accommodated before km Ta in rotor case connected to the axial direction , the spacer is interposed between the rotor casing, and said spacer and each of the rotor casing are joined by dowel pins, the spacer is a material specific gravity is smaller than the rotor, the outer diameter of the spacer is the The inner diameter of the rotor case is smaller than the outer diameter of the rotor case, and a step to be fitted to the outer periphery of the spacer is provided. and is stopped, the have detent between the rotor case and the spacer is made Turkey The features.
Further, the present invention is characterized in that the rotor is iron-based and the spacer is aluminum-based .

  According to the present invention, since the spacer is a material having a specific gravity smaller than that of the rotor, the weight can be reduced.

It is a perspective view of the multistage oil pump of one embodiment of the present invention. It is a front view of the multistage oil pump of FIG. It is the disassembled perspective view which looked at the multistage oil pump of FIG. 1 from the cover side. It is the disassembled perspective view which looked at the multistage oil pump of FIG. 1 from the housing side. It is the disassembled perspective view which looked at the multistage oil pump of FIG. 1 from the cover side. It is the disassembled perspective view which looked at the multistage oil pump of FIG. 1 from the housing side. It is AA arrow sectional drawing of FIG. It is a figure which shows the flow of the oil in a multistage oil pump.

  Hereinafter, the best mode of the present invention will be described with reference to the drawings.

  As shown in FIGS. 1 to 6, the multistage oil pump 1 includes a housing 2, a cover 3 that closes the housing 2, a rotor case 4 accommodated in the housing 2, and a rotor case 4 that is accommodated in a row. The first and second rotors 6 and 7 are provided.

  The housing 2 has a bottomed cylindrical shape and includes a pump discharge port 21 and a fitting hole 22. A fitting hole 31 is formed in the cover 3. The rotor case 4 is divided into a first rotor case 41 and a second rotor case 42 in the axial direction, and the first rotor case 41 and the second rotor case 42 are partitioned by a spacer 5.

  The first rotor case 41 accommodates the first rotor 6, and the second rotor case 42 accommodates the second rotor 7. The first rotor case 41 is formed with a circular first rotor accommodation hole 411 having a shaft eccentric with respect to the first rotor case 41 and a fitting hole 412. The second rotor case 42 is formed with a circular second rotor accommodation hole 421 having a shaft eccentric with respect to the second rotor case 42 and a fitting hole 422. The first rotor case 41 and the second rotor case 42 are disposed in the housing 2 with the first rotor accommodation hole 411 and the second rotor accommodation hole 421 offset in the axis.

  The spacer 5 is a disc having the same outer diameter as the first rotor case 41 and the second rotor case 42, and the insertion hole 51 of the drive shaft 11, the first rotor discharge port 52, the second rotor suction port 53, and the first rotor suction A port 54 is provided. The first rotor discharge port 52 is formed on one surface of the spacer 5, and the second rotor suction port 53 is formed on the other surface of the spacer 5, and communicates with each other. Dowel pins 8 project from one side and the other side of the spacer 5, respectively. The dowel pin 8 is made of SUJ (high carbon bearing steel).

  The spacer 5 is made of an aluminum material having a specific gravity smaller than that of the first and second rotors 6 and 7. As the aluminum-based material, specifically, ADC12, ADC10, ADC14 (for die casting), AC2A, AC4B (for sand casting), A2014, A2017 and the like can be used.

  Between the 1st rotor case 41 and the cover 3, the side plate 9 and the sealing material 12 are arrange | positioned in this order from the 1st rotor case 41 side. The side plate 9 is configured by providing an insertion hole 91, a purge port 92, and a fitting hole 94 of the drive shaft 11 on a disk having the same outer diameter as the first rotor case 41. The sealing material 12 seals between the cover 3 and the side plate 9.

  The dowel pin 8 protruding from one surface of the spacer 5 is fitted into the fitting hole 422 of the second rotor case 42 and the fitting hole 22 of the housing 2, and the second rotor case 42 and the housing 2 are connected as shown in FIG. 7. It is joined to the spacer 5. The dowel pin 8 protruding from the other surface of the spacer 5 is fitted into the fitting hole 412 of the first rotor case 41, the fitting hole 94 of the side plate 9, and the fitting hole 31 of the cover 3. The side plate 9 and the cover 3 are joined to the spacer 5.

  The first rotor 6 is configured by disposing a first inner rotor 62 inside the first outer rotor 61, and is formed of an iron-based material. Specifically, iron-copper-carbon (JPMA standard), SMF4030, or the like can be used as the iron-based material. The first outer rotor 61 is configured by providing an oil filling hole 611 in a disc having an outer diameter substantially equal to the inner diameter of the first rotor accommodation hole 411, and is rotatably arranged in the first rotor accommodation hole 411. Has been. The oil filling hole 611 is disposed so that the first outer rotor 61 and the shaft center coincide with each other.

  Between the first outer rotor 61 and the first inner rotor 62, there are four partitions partitioned by the inner peripheral surface of the oil filling hole 611, the outer peripheral surface of the first inner rotor 62, the spacer 5 and the side plate 9. An oil storage chamber is configured.

  The first inner rotor 62 is fixed to the drive shaft 11 and is disposed in the first outer rotor 61 such that the axis of the drive shaft 11 coincides with the axis of the first rotor case 41.

  The second rotor 7 is configured by arranging a second inner rotor 72 inside the second outer rotor 71. The second outer rotor 71 has the same shape as the first outer rotor 61 and is rotatably disposed in the second rotor accommodation hole 421. The second inner rotor 72 has the same shape as the first inner rotor 62 and is arranged in the second outer rotor 71 such that the axis of the drive shaft 11 coincides with the axis of the second rotor case 42. Has been.

  Between the second outer rotor 71 and the second inner rotor 72, there are four oil storage chambers partitioned by the inner peripheral surface of the oil filling hole 611, the outer peripheral surface of the second inner rotor 72, and the housing 2. It is configured.

Next, a method for assembling the multistage oil pump 1 will be described.
First, the drive shaft 11 is inserted into the spacer 5 and positioned with a pin, the inner rotor is assembled to the drive shaft 11, and the outer rotors 61 and 71 are fitted to the inner rotors 62 and 72. Subsequently, the dowel pins 8 are attached to the spacer 5, the rotor cases 41 and 42 are assembled to one surface and the other surface of the spacer 5, and the side plate 9 is assembled to the second rotor case 42. After the temporary assembly as described above, the cover 3 is accommodated in the housing 2 and the cover 3 is attached in the housing 2.

  Next, the operation of the multistage oil pump 1 will be described.

  As shown in FIG. 8, oil is supplied to the oil storage chamber of the first rotor 6 from the first rotor suction port 54. When the drive shaft 11 rotates, the first outer rotor 61 is rotated in the rotation direction of the drive shaft 11 by the first inner rotor 62, and the oil storage chamber also moves around the drive shaft 11. The oil storage chamber increases in volume as it moves away from the drive shaft 11, and sucks that much oil from the first rotor suction port 54. Further, the oil storage chamber decreases in volume as it approaches the drive shaft 11, and the corresponding amount of oil is discharged from the purge port 92 and the first rotor discharge port 52.

  Oil is supplied to the oil storage chamber of the second outer rotor 71 from the second rotor suction port 53. When the drive shaft 11 rotates, the second outer rotor 71 is rotated in the rotation direction of the drive shaft 11 by the second inner rotor 72, and the oil storage chamber also moves around the drive shaft 11. The oil storage chamber increases in volume as it moves away from the drive shaft 11, and sucks that much oil from the second rotor suction port 53. The oil storage chamber decreases in volume as it approaches the drive shaft 11, and the oil corresponding to that volume is discharged from the oil discharge port 21.

  The oil discharged from the first rotor discharge port 52 by the oil storage chamber of the first rotor 6 is sucked into the oil storage chamber of the second rotor 7 from the second rotor suction port 53. Since the first rotor accommodating hole 411 is offset with respect to the second rotor accommodating hole 421, the oil accommodating chamber of the second rotor 7 increases in volume as the oil accommodating chamber of the first rotor 6 increases in volume. Decrease. Therefore, the oil discharged from the first rotor discharge port 52 is directly sucked from the second rotor suction port 53 by the oil storage chamber of the second rotor 7 that increases the volume.

  According to the present embodiment, since the spacer 5 is a material having a specific gravity smaller than that of the rotors 6 and 7, the weight can be reduced.

  Further, according to this embodiment, since the rotors 6 and 7 are iron-based and the spacer 5 is aluminum-based, occurrence of seizure between the rotors 6 and 7 and the spacer 5 can be suppressed.

  In the above embodiment, the case where the spacer 5 is made of aluminum has been described. However, the spacer 5 may be made of magnesium. The joining method of the spacer 5 and the rotor cases 41 and 42 with the dowel pins 8 is arbitrary. For example, the outer diameter of the spacer 5 is made smaller than the outer diameter of the rotor cases 41 and 42, The inner peripheral portion is provided with a step to be fitted to the outer peripheral portion of the spacer 5, and the pins such as the dowel pins 8 are fixed to the fitting portions of both from the outside of the rotor cases 41, 42, so that the rotor cases 41, 42 and the spacer 5 It is good also as a structure which performs rotation prevention between.

  Moreover, although the said embodiment demonstrated the case where oil was supplied to the oil storage chamber in the 1st outer rotor 61 from the spacer 5 side of the side surface of the rotor case 4, it is good also as a structure supplied from the cover 3 side. . Alternatively, the oil may be supplied from the cover 3 through the housing 2 into the oil storage chamber.

DESCRIPTION OF SYMBOLS 1 Multistage oil pump 11 Drive shaft 12 Seal material 2 Housing 21 Pump discharge port 22 Fitting hole 3 Cover 31 Fitting hole 4 Rotor case 41 First rotor case 411 First rotor accommodation hole 412 Fitting hole 42 Second rotor case 421 Second rotor housing hole 422 Fitting hole 5 Spacer 51 Insertion hole 52 First rotor discharge port 53 Second rotor suction port 54 First rotor suction port 6 First rotor 61 First outer rotor 611 Oil filling hole 62 First inner rotor 7 Second rotor 71 Second outer rotor 711 Oil filling hole 72 Second inner rotor 8 Dowel pin 9 Side plate 91 Insertion hole 92 Purge port 94 Fitting hole

Claims (2)

A multi-stage oil pump in which a plurality of rotors are connected in series,
Axially connected before km Ta in the rotor case was is housed,
The spacer is interposed between the rotor cases, the spacers and the rotor cases are joined by dowel pins,
Wherein the spacer is a material specific gravity is smaller than the rotor,
The outer diameter of the spacer is smaller than the outer diameter of the rotor case,
The inner periphery of the rotor case is provided with a step fitted to the outer periphery of the spacer,
Said from the outside of the rotor case is stopped is the dowel pin in the fitting portion of the rotor case and the spacer, multistage oil pump, wherein Rukoto detent taking place between the said spacer and the rotor case .   The multistage oil pump according to claim 1, wherein the rotor is iron-based and the spacer is aluminum-based.