JP5993219B2 - How to use the Pendulum Slider Pump and Pendulum Slider Pump - Google Patents

Description

  The present disclosure relates to a pendulum slider pump, and more particularly to a pendulum slider pump that supplies a lubricant such as oil to a combustion engine.

  The use of flow-controlled pendulum slider pumps in combustion engines has been at the forefront of technology for many years, for example, to easily adjust discharge and pressure to combustion engine requirements. Such adjustment is usually done by loading the slider in the pendulum slider pump with the oil pressure generated from the main oil gallery of the combustion engine.

  Patent Document 1 describes a general pendulum slider pump that supplies a lubricant, particularly oil, to a combustion engine. Here, a displaceable outer rotor that rotates in the same way via an inner rotor and a pendulum drive is used. For rotational drive from the inner rotor to the eccentrically displaceable outer rotor, only one pendulum driver with drive head, drive leg and only one sliding flank are always in sliding contact. The outer rotor is displaced to control the discharge rate.

  Other pendulum slider pumps are described in Patent Document 2 and Patent Document 3, for example.

German Patent Invention No. 19532703 German utility model application publication No. 3630515 German Utility Model Application Publication No. 3624532

  The pendulum slider pump is desired to further improve its function, for example.

  The present invention provides an improved or at least alternative embodiment for a general type of pendulum slider pump, and is particularly characterized by improved functionality.

  According to the invention, the above problem is solved by the subject matter of the independent claims. Advantageous embodiments are, for example, the subject matter of the dependent claims.

  The present invention is based on the general idea of reversing the mounting of individual pendulums while maintaining the known operating principle of the pendulum slider pump. In the pendulum slider pump according to the invention, the pendulum is no longer hinged on the outer rotor, but rather hinged on the inner rotor and within the associated pendulum guide in the outer rotor. Guided in the radial direction. In addition, the pendulum slider pump can provide two different discharge pressures. The two discharge pressures can each be assigned to other, different circuits. However, the associated media are not different types, because a slightly mixed amount is unavoidable. Here, the pendulum slider, the inner rotor, and the outer rotor form a chamber for the first pressure stage of the pendulum slider pump, and the pendulum slider and the outer rotor form a chamber for the second pressure stage of the pendulum slider pump. Here, the first pressure stage can be realized as a low pressure stage, and the second pressure stage can function as a high pressure stage. By providing or generating at least two different pressure levels, one and the same pendulum slider pump can accommodate different applications, for example, the compressed pump medium in the high pressure stage is used to shift the transmission, On the other hand, the low pressure stage can be used simply for cooling / lubrication. Roughly, the function of the pendulum slider pump is enhanced by this because it can provide different discharge pressures at the same time.

  The pendulum slider pump can be driven by an external motor, an electric motor, or a combustion engine. The transmission of force and rotational speed can be done either through a shaft that drives the inner rotor or through an outer rotor that is driven from the outside.

  The method of manufacturing the inner rotor, outer rotor, pendulum, and other individual components can be sintering, casting, punching or other methods. The manufacturing method to be selected depends on the planned configuration of the pendulum slider pump. The material may also be a different metal or alloy, or plastic depending on the requirements of the pendulum slider pump.

  According to a further advantageous development of the invention, the pendulum slider pump may not be mechanically driven externally, for example by a belt or chain drive, but may be part of the electric motor itself. Driving is performed by an electric motor through an external rotor. For this purpose, a magnet, in particular a permanent magnet, is placed in a suitable recess in the outer rotor, while a stator with an electromagnet is placed outside the outer rotor. The magnet and electromagnet in this case constitute a component of an electric motor type drive for driving the pendulum slider pump. For example, the outer rotor can be formed as a cost-effective sheet metal part. In this case, a recess for receiving the magnet is also formed at the same time. This makes it possible to drive a pendulum slider pump that is compact in design, cost effective and independent of an external power source.

  The pendulum slider pump according to the invention serves, for example, to supply lubricant to the combustion engine, in particular to supply oil. Alternatively, other liquid media such as water, coolant, or the like can be used. Its use is not limited to automobiles or combustion engines. The present invention can be used in both a moving body and a stationary body.

  The pendulum slider pump according to the invention comprises an inner rotor mounted for rotation. The inner rotor is connected to the outer rotor via the aforementioned pendulum. The inner rotor of the pendulum slider pump according to the invention compared to the pendulum slider pumps known from the prior art, wherein the pendulum is hinged on the outer rotor and guided radially in the inner rotor Can be designed significantly smaller. For this reason, it can be significantly reduced in size and, as a result, an advantage of a package that cannot be underestimated can be obtained. The operating principle of the pendulum slider pump according to the present invention is the same as that of a conventionally known pendulum slider pump. The main advantages of the pendulum slider pump according to the invention are in particular the omission of high material, the requirement for mounting space for the inner rotor, and the reduction of the complexity of the outer rotor. This is due to the fact that the pendulum head surrounded by more than 180 ° is now arranged on the inner rotor. By using a completely different configuration of the outer rotor, it is possible in addition to making the outer rotor all from other materials and from other manufacturing methods, for example in a simple shape with suitable recesses for magnets. Sheet metal parts may be used for this purpose. In contrast, the inner rotor may be left as it is, for example as a sintered part.

  Further important features and advantages of the invention result from the subclaims, from the drawings and from the description of the associated figures by means of the drawings.

  The features described above and described below can be used not only in the respective combinations described, but also in other combinations or by themselves without departing from the scope of the invention. it can.

  Preferred exemplary embodiments of the invention are illustrated in the drawings and are explained in more detail in the following description. Wherever possible, the same reference numbers indicate the same, similar or functionally identical elements.

It is sectional drawing in 1st Embodiment of the pendulum slider pump by this invention. It is a figure of 2nd Embodiment. It is sectional drawing which shows the different drive method of the pendulum slider pump by this invention.

  Referring to FIGS. 1-3, a pendulum slider pump 1 according to the present invention specifically designed for supplying a lubricant, such as oil, to a combustion engine (not shown) is rotatable, particularly an internal rotor. 2 is rotatably mounted. The inner rotor 2 is connected to the outer rotor 4 via the pendulum 3. According to the invention, the pendulum 3 is hinged on the inner rotor 2 and guided radially in the outer rotor 4. The pendulum 3 includes a pendulum head 6 and a pendulum leg 14. The pendulum head 6 is rotatably mounted on the inner rotor 2 and the pendulum leg 14 is mounted in a pendulum guide 5 on the outer rotor 4 so as to be movable, in particular radially displaceable.

  In the pendulum slider pump 1 according to the invention, the inner rotor 2 can be configured significantly more compactly and simply because of the omitted radial guides. A pendulum guide 5 provided for the radial guide of the pendulum 3 is provided on the outer rotor 4. As a result, the outer rotor 4 has a larger radial extension than conventionally known outer rotors. In spite of this, the advantage of the mounting space, which is obtained by the clearly more compact design of the inner rotor 2, is superior, so that a particularly large discharge amount is also possible.

  At the same time, the pendulum slider pump 1 according to the invention can also be used to generate two different pressure levels. This forms a chamber 8 in which the pendulum 3, the inner rotor 2, and the outer rotor 4 are the first pressure stage, and a chamber 9 in which the pendulum 3 and the outer rotor 4 in the pendulum guide 5 are the second pressure stage. Because. Here, the first pressure stage can be realized, for example, as a low pressure stage, while the second pressure stage is used as a high pressure stage. Therefore, there is a pressure level in chamber 9 that is different from that in chamber 8, in particular a higher pressure level. The low pressure stage may be connected in series with the high pressure stage, for example, in the sense of a prestage.

  In order to control the rate of delivery of the pendulum slider pump 1 according to the invention, the inner rotor 2 and the outer rotor 4 can be received in an adjustable slider 15. The adjustable slider 15 can control the discharge amount by changing the eccentricity of the inner rotor 2 with respect to the outer rotor 4 by adjustment. While this eccentricity can be achieved by displacing the outer rotor 4 compared to the inner rotor 2, it can also be achieved by concentrating the inner rotor 2 with respect to the outer rotor 4. Which of the rotors 2 and 4 is adjusted depends on the driving concept of the pendulum slider pump 1. When driven externally via the shaft 16, the outer rotor 4 can actually be moved by the outer slider 15. The outer rotor 4 is preferably rotatably mounted on the outer slider 15 in the contact area 17 with low friction. Alternatively, when driving the pendulum slider pump 1 through the outer rotor 4, the inner rotor 2 is displaced by the shaft 16. This is practical when, for example, the pendulum slider pump 1 itself forms part of an electric motor as shown in FIG.

  Advantageously, the pendulum slider pump 1 can be driven by an electric motor via the outer rotor 4. For that purpose, a magnet 11 is arranged in a suitable recess 10 in the outer rotor 4, and a stator 12 having an electromagnet 13 such as a coil is arranged outside the outer rotor 4. The magnet 11 and the electromagnet 13 in this case form a part of an electric motor driving unit for driving the pendulum slider pump 1. Due to the electric motor drive, the pendulum slider pump 1 of the present invention does not depend on conventional mechanical drive via, for example, a chain or belt drive. In this case, the inner rotor 2 is rotatably mounted on the shaft 16 and external driving may not be applied. Of course, the external drive of the pendulum slider pump 1 can be realized via the shaft 16, and in this case, the inner rotor 2 is connected to the shaft 16 in a fixed state so as not to rotate with respect to the shaft 16.

  The letters S and N shown in FIG. 3 represent permanent magnets attached at this position and always have N and S poles. However, this is only an example of a preferred alternating arrangement of magnets.

  In general, the outer rotor 4 with the pendulum slider pump 1 according to the invention can be designed as a cost-effective shaped sheet metal part for attaching the pendulum heads 6 of the individual pendulums 3 conventionally arranged. Because the pendulum head mountings are no longer needed. In the circumferential direction between the individual pendulum guides 5, the magnet 11 can be further provided in a suitable recess 10. As a result, the outer rotor 4 can be electrically driven. Referring to FIGS. 1 and 2, each pendulum slider pump 1 shown has an arbitrary number of pendulum sliders 3.

  The pendulum slider 3 and the recess 10 shown in all figures are not to be understood in a limited way, but rather serve only to illustrate the basic configuration of the pendulum slider pump 1 according to the invention. The number of pendulums 3 may be even or non-even. The number of recesses 10 need not necessarily be related to the number of pendulums 3.

  FIG. 2 shows a pendulum slider pump 1 where each pendulum 3 is further hinged to an associated piston 7. The piston 7 is guided into a radial pendulum guide 5 in the outer rotor 4. Similar to the pendulum slider pump 1 according to FIG. 1, such a piston 7 is realized unitarily with the pendulum 3. The piston 7 on the pendulum slider 3 minimizes the leakage rate between the two chambers 8 and 9 of different pressure stages. Thereby, very different pressure levels can be realized more easily.

  According to the pendulum slider pump 1 according to the invention, the use of other materials / manufacturing methods for the outer rotor 4 is also feasible, in particular the latter has a suitable recess 10 for a magnet 11, for example, which is cost effective. Can be produced as sheet metal parts of good shape. By providing a radial pendulum guide 5 in the outer rotor 4, the conventionally required pendulum head fitting can be omitted. As a result, the complexity of the outer rotor 4 can be reduced. The pendulum head mounting by the pendulum slider pump 1 according to the present invention is provided by the inner rotor 2 designed as a sintered part and may be cost effective, for example.

1 Pendulum Slider Pump 2 Inner Rotor 3 Pendulum 4 Outer Rotor 5 Radial Pendulum Guide 6 Pendulum Heads 8 and 9 Chamber 10 Recess 14 Pendulum Leg 15 Outer Slider 16 Shaft

Claims (8)

A pendulum slider pump (1) having a rotatable inner rotor (2) connected to an outer rotor (4) via a pendulum (3),
The pendulum (3) is hinged to the inner rotor (2) and guided radially in the outer rotor (4);
The pendulum (3), the inner rotor (2) and the outer rotor (4) form a chamber (8) of the first pressure stage of the pendulum slider pump (1), the pendulum (3) and the outer rotor (4) Forming the chamber (9) of the second pressure stage of the pendulum slider pump (1) ;
The first pressure stage is designed as a low pressure stage and the second pressure stage is designed as a high pressure stage;
Pendulum slider pump. The pendulum slider pump according to claim 1 , wherein the low pressure stage is connected in series with the high pressure stage. In the outer rotor (4), the magnet (11) is disposed in the recess (10),
Outside the outer rotor (4), a stator (12) having an electromagnet (13) is arranged,
The pendulum slider pump according to any one of claims 1 to 2 , wherein the magnet (11) and the electromagnet (13) form part of an electric motor driving force for driving the pendulum slider pump (1). Each pendulum (3) is hinged to the associated piston (7)
The pendulum slider pump according to any one of claims 1 to 3 , wherein the piston is guided in a radial pendulum guide (5) in the outer rotor (4). The inner rotor (2) or the outer rotor (4) is received in an adjustable slider, and a discharge amount of the pendulum slider pump (1) is controlled via the adjustable slider. 5. The pendulum slider pump according to any one of 4 . Wherein said at first and second chambers (8,9), pendulum slider pump according to any one of claims 1 to 5, similar or identical pump medium is provided with different pressures. The pendulum slider pump according to any one of claims 1 to 6 , wherein the outer rotor (4) is designed as a sheet metal part having a shape. Using pendulum slider pump according to any one of claims 1 to 7 in the vehicle using a combustion engine or a hybrid drive or an electric drive.

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