阅读说明：本技术 将力从凸轮轴传递到输出装置的设备 (Device for transmitting force from a camshaft to an output ) 是由 M·莫伦 于 2020-10-12 设计创作，主要内容包括：本公开总体上涉及一种用于将力从旋转的凸轮轴传递到输出装置的力传递设备,其能够减小凸轮轴上的横向力。所提出的连接装置力传递设备被配置为使力从基本相反的方向作用在凸轮轴上,这在凸轮轴上有效地产生接近零的合力,或者与现有技术的力传递方案相比至少减小。因此,凸轮轴上的横向力减小并因而例如支撑凸轮轴的轴承上的横向力减小,从而延长轴承的寿命。(The present disclosure generally relates to a force transmission apparatus for transmitting force from a rotating camshaft to an output device, which is capable of reducing lateral force on the camshaft. The proposed coupling device force transmission apparatus is configured such that forces act on the camshaft from substantially opposite directions, which effectively results in a near zero resultant force on the camshaft, or at least reduced compared to prior art force transmission solutions. As a result, the transverse forces on the camshaft and thus on the bearings supporting the camshaft, for example, are reduced, thereby extending the life of the bearings.)

1. A force transmission apparatus for transmitting force from a rotating camshaft to an output device, the force transmission apparatus comprising:

a first transmission element in contact with the camshaft and configured to transmit force from the camshaft to the output device when the camshaft is rotating;

a second transmission element in contact with the camshaft and configured to transmit a force from the camshaft to the output device when the camshaft rotates,

wherein the forces on the camshaft caused by the first and second transmission elements when transmitting forces to the output element are in substantially opposite directions.

2. The force transmission device of claim 1,

wherein the first transfer element is arranged to be pushed away from the rotational axis of the camshaft in a first direction when transferring force to the output device,

wherein the second transfer element is arranged to be pushed away from the rotational axis of the camshaft in a second direction when transferring force to the output device, wherein the first direction is substantially opposite to the second direction.

3. Force transmission device according to any one of claims 1 and 2, wherein the first transmission element is arranged to be pushed away by the camshaft in the first direction while the second transmission element is pushed away in the second direction.

4. The force transmission apparatus of any preceding claim, wherein the first transmission element is rotationally attached adjacent the camshaft and rotatable about an axis of rotation, wherein the first transmission element comprises a contact portion and a transmission portion, the contact portion being in contact with the camshaft, wherein the transmission portions are arranged to move in substantially opposite directions when the contact portion is pushed away from the axis of rotation of the camshaft, thereby transmitting force to the output device.

5. The force transmission apparatus according to claim 4, wherein the first transmission portion is arranged to push on a link arm when the first transmission element rotates, thereby transmitting the force from one side of the camshaft to the output device.

6. The force transfer apparatus of any preceding claim, wherein the second force transfer element is arranged to be linearly displaced as the camshaft rotates to transfer force to the output element.

7. Force transfer apparatus according to claim 6 in which the second force transfer element is arranged for linear displacement towards the output device.

8. Force transmission device according to any one of the preceding claims, wherein the first transmission element is mechanically coupled to the second transmission element.

9. The force transmission apparatus of claim 8, wherein the first and second transmission elements are arranged such that the forces transmitted by the first and second transmission elements to the output device add to each other.

10. The force transmission apparatus of any one of the preceding claims, wherein the first transmission element and the second transmission element are arranged to be pushed by the same cam on the camshaft.

11. The force transmission apparatus of any one of the preceding claims, wherein the first and second transmission elements are arranged to be pushed by cams arranged on opposite sides of the camshaft.

12. The force transmission apparatus of any one of the preceding claims, wherein the first and second transmission elements are arranged to be urged by a cam having a profile matching the position of a respective one of the first and second transmission elements.

13. The force transmission apparatus of any of the preceding claims, wherein a spring is provided to provide a reaction force to the first and second transmission elements such that the first and second transmission elements remain in contact with the camshaft.

14. The force transmission apparatus of any one of the preceding claims, wherein the output device is adapted to control a fuel pump.

15. A vehicle engine comprising a camshaft, an output device, and a force transmission apparatus according to any preceding claim.

Technical Field

The present disclosure relates to a force transmission apparatus for transmitting force from a rotating camshaft to an output device.

Background

Internal combustion engines rely on critical timing of air/fuel injection and exhaust using piston strokes. Control of the valves and fuel pumps is typically effected by a camshaft which rotates in a synchronous manner with the crankshaft via a belt or chain. Crankshaft rotation is caused by piston motion.

The camshaft comprises a shaft and at least one (usually several) cams arranged on said shaft. When the shaft rotates, the cam moves about the axis of rotation of the shaft and causes a force on the control element to open or close a valve or cause a fuel pump to inject fuel, for example, depending on the rotational position of the camshaft.

The camshaft is supported by bearings so as to allow it to rotate with little resistance. In general, such bearings should preferably not be exposed to radial forces transverse to the main axis of the camshaft in order to ensure a satisfactory life of the bearings.

Disclosure of Invention

The present disclosure relates generally to a force transmission apparatus for transmitting force from a rotating camshaft to an output device, which can reduce lateral force on the camshaft, thereby improving the life of the camshaft and bearings, and also reduce vibration caused by lateral force on the camshaft.

The proposed force transmission device is configured such that the forces act on the camshaft from substantially opposite directions, which effectively results in a near zero total force on the camshaft, or at least reduced compared to prior art force transmission solutions. Thus, the transverse forces on the camshaft and thus, for example, on the bearings supporting the camshaft are reduced, whereby the life of the bearings is extended and problems relating to noise, vibration, and harshness can be reduced.

The above-mentioned advantages arise by allowing both force transmitting elements to be in contact with the camshaft when transmitting force to the same output element in such a way that they simultaneously cause a resultant force directed substantially towards each other when they transmit force to the output element. In other words, the main part of the force caused by the first force transmitting element on the camshaft is in the opposite direction to the main part of the force caused by the second force transmitting element on the camshaft.

More specifically, the inventors propose a force transmission apparatus for transmitting force from a rotating camshaft to an output device. The force transmitting apparatus includes a first transmission element in contact with the camshaft and configured to transmit force from the camshaft to the output device when the camshaft rotates. Further, a second transmission element is in contact with the camshaft and configured to transmit force from the camshaft to the output device when the camshaft is rotating. The forces on the camshaft caused by the first and second transmission elements are in substantially opposite directions when transmitting forces to the output element.

Further features of, and advantages with, embodiments of the present disclosure will become apparent when studying the appended claims and the following description. Those skilled in the art realize that different features of the present disclosure can be combined to create embodiments other than those described in the following, without departing from the scope of the present disclosure.

Drawings

These and other aspects of the present disclosure will now be described in more detail, with reference to the appended drawings showing exemplary embodiments of the disclosure, wherein:

FIG. 1 illustrates an exemplary combustion engine for a vehicle;

FIG. 2 conceptually illustrates a camshaft including a cam that applies a force to an output device;

FIG. 3 illustrates an exemplary prior art apparatus;

figure 4A conceptually illustrates one embodiment of a force-transmitting device, in accordance with embodiments of the present disclosure; and

figure 4B conceptually illustrates one embodiment of a force-transmitting device, in accordance with embodiments of the present disclosure.

Detailed Description

Various embodiments of a force transfer device according to the present disclosure are described in this detailed description. Embodiments of the present disclosure may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided for thoroughness and completeness, and fully convey the scope of the invention to the skilled person. Like reference numerals refer to like elements throughout.

FIG. 1 conceptually illustrates an exemplary combustion engine 100 for a vehicle. The combustion engine includes a plurality of cylinders (not shown) and a plurality of pistons 104. A respective piston 104 is disposed in each of the cylinders. The pistons 104 are forced to move in the respective cylinders by ignition of the fuel in the cylinder volumes. The stroke motion of the pistons in the cylinders is transferred to a crankshaft 108 for transmitting propulsive power to a driveline (not shown) of a vehicle including the combustion engine 100.

Further, to allow air to mix with fuel in the cylinder volume, the valves 109 (only one of the several valves is numbered) are configured to open air inlets to the cylinder volume at timed intervals (timed intervals). This timing is provided by a linkage 111 (a so-called "timing belt") configured to rotate the first camshaft 110 about the axis of rotation 112 such that the cams 114 of the camshaft 110 cause the first valve 109 to open and close in a synchronized manner relative to the rotation of the crankshaft and thus relative to the stroke of the piston 104.

Further, the second camshaft 118 is configured to open and close second valves 120 (only one numbered). The timing of the operation of the second valve 120 is also provided by the linkage 111. Thus, the linkage mechanism is configured to rotate the second camshaft 118 about the rotation axis 115 such that the cams 116 of the second camshaft 118 open and close the second valves 120 in a synchronized manner relative to the rotation of the crankshaft 108 and thus relative to the stroke of the pistons 104.

The second valve 120 may control the flow of exhaust gas from the cylinder volume in a manner synchronized with the rotation of the crankshaft 108 and thus the stroke of the piston 104.

The configuration of engine 100 shown in fig. 1 is purely exemplary and should not be construed to limit the scope of the appended claims. For example, the camshaft may be arranged to additionally control a fuel pump or oil pump or other exemplary output device.

Fig. 2 conceptually illustrates a partial camshaft 200 having conceptual cams 202. When the camshaft 200 rotates and a wider portion of the cam 202 is aligned with the pushing element 204, the cam 202 is in contact with the pushing element 204 adapted to be pushed toward the spring 206. When the narrower portion of the cam 206 is aligned with the pushing element 204, the spring 206 expands and pushes the pushing element 204 in a direction toward the camshaft 200 such that the pushing element 204 remains in contact with the cam 202. The pushing element 204 is arranged to control an output device 208 adapted to control, for example, a fuel pump or an oil pump. For example, when the pushing element 204 is pushed away from the camshaft 200 and thereby compresses the spring 206, the fuel pump may be caused to inject fuel into the engine of the vehicle.

Fig. 3 shows an exemplary prior art arrangement. Here, camshaft 200 includes cam 202, cam 202 having a wide dimension 210 and a narrow dimension 212. The coupling element 214 is here arranged to control a conceptually shown fuel pump 211. The spring 204 ensures that the coupling element 214 is in contact with the camshaft 202. Thus, when the camshaft rotates and moves the coupling element 214 by means of the cam profile, the coupling element 214 causes the spring 204 to compress while the fuel pump 211 is controlled by the movement. When the camshaft 200 causes the output 214 to compress the spring 204, a reaction force 216 acts on the camshaft and, therefore, also on the bearings that support the camshaft 200. This force 216 acts transverse to the axis of the camshaft and causes a fracture (tear) in the bearings and support structure of the camshaft 200. Embodiments of the present disclosure alleviate this problem.

Figure 4A conceptually illustrates an embodiment of a force-transmitting device, in accordance with embodiments of the present disclosure. Thus, figure 4A conceptually illustrates a force transmission apparatus 400 for transmitting force from a rotating camshaft 402 to an output device 403. The force transmitting apparatus 400 includes a first transmission element 404, the first transmission element 404 being in contact with the camshaft 402 and configured to transmit force from the camshaft 402 to the output device 403 when the camshaft is rotated. The second transmission element 406 is in contact with the camshaft 402 and is configured to transmit force from the camshaft 402 to the output device 403 when the camshaft 402 is rotated. The forces on the camshaft 402 caused by the first and second transfer elements 404, 406 are in substantially opposite directions when transferring the forces to the output element.

Fig. 4A shows the camshaft 402 in a rotational orientation in which the narrow dimension 410 of the cam 408 is substantially aligned with the force transmitting elements 404 and 406 such that they cause little or no lateral effect on the output 403, in other words, the output is in a first position, which may be a retracted position.

Fig. 4B shows the force transmission apparatus 400 when the camshaft 402 has rotated such that the wide portion 412 of the cam 408 causes the force transmission element 404 to be pushed away from the axis of rotation of the camshaft 402 in a first direction to transmit force to the output device 403. Furthermore, with the camshaft 402 in this orientation, the second force transmitting element 406 is arranged to be pushed away from the rotational axis of the camshaft in the second direction when transmitting a force to the output device 403. The first direction is substantially opposite the second direction. Preferably, the first transfer element 404 may be arranged to be pushed away by the camshaft 402 in a first direction, while the second transfer element is pushed away in a second direction.

The force 416 induced on the camshaft 402 by the first transfer element 404 is in an opposite direction to the force 418 induced by the second transfer element 404, with substantially equal magnitude (amount), and preferably with a major portion of the force in the opposite direction. The resulting force on the camshaft is therefore substantially zero.

The inventors have thus realized that by arranging for two force transmitting elements to act simultaneously on a camshaft to transmit forces to the same output device such that they act at least partly in opposite directions on the camshaft, the resultant force on the camshaft can be at least reduced. Thereby, it is possible to reduce wear on the camshaft and the bearings supporting the camshaft, and to extend their life. Furthermore, by means of embodiments of the present disclosure, potential NVH (noise, vibration, Harshness) issues associated with clearances in camshaft bearings are minimized.

Forces acting on the camshaft in generally opposite directions should be broadly construed to include at least one component of the force acting in an opposite direction. Preferably, the main parts/components of the forces act in opposite directions, so that the resultant force is kept as small as possible. However, as illustrated in fig. 4B, deviation from the reverse direction is allowed. The same applies to the fact that the force-transmitting elements can be arranged to be pushed away in substantially opposite directions, i.e. to deviate from opposite directions, as long as the resultant force on the camshaft remains small.

The general inventive concept of the present disclosure may be achieved in various ways with the object of reducing transverse forces on the camshaft by configuring the first and second transmission elements such that the forces on the camshaft are in substantially opposite directions when transmitting forces to the output element. One such possible embodiment will now be described in more detail with reference to fig. 4A-B.

Turning to fig. 4A-B, the first transfer element 404 is rotatably attached adjacent the camshaft and rotatable about an axis of rotation 420, wherein the first transfer element comprises a contact portion 422 and a transfer portion 424, the contact portion 422 being in contact with the camshaft 402, wherein the transfer portion 424 is arranged to move in substantially opposite directions when the contact portion 422 is pushed away from an axis of rotation 426 of the camshaft 402, thereby transferring force to the output device 403. In other words, the first force transmitting element 404 is rotated about its rotational axis 420 by the force applied thereto by the camshaft 402. The rotation causes the transmitting portion to travel along the circumference of the rotational movement and thereby transmit force towards the output device 403. Thereby, a possible way of enabling the force to be transmitted from one side of the main axis of the camshaft 402 to the other side where the output 403 is located is provided.

The first transfer element 404 comprises a contact portion 422 arranged to receive a force from the cam 408 of the camshaft. Furthermore, the first force transmission element has an extension (transmission part 424) which reaches beyond the camshaft width so that it can transmit force to the other side of the main axis of the camshaft 402. In fig. 4A-B, the transmitting portion 424 reaches above the camshaft 402. To this end, the length of the first transfer element 404 from the contact portion 422 to the transfer portion 424 exceeds the width of the camshaft, preferably the width of the wide portion 412 of the cam 408.

The contact portion 422 may be configured as a rolling element 423, shown here conceptually, the rolling element 423 being supported by a bearing 425, shown here conceptually, such that the rolling element rotates as it moves along the outer circumference of the cam 408.

The transmission part 424 may be arranged to push on the link arm 428 when the first transmission element 404 rotates, thereby transmitting force from one side of the camshaft to the output 403. The link arm may be disposed in a guide channel 430 of the engine. The coupling between the link arm 428 and the transfer element 424 does not require the link arm 428 and the transfer element 424 to be mechanically attached to each other. The link arm may have a substantially flat surface that is brought into contact with the transfer element 428 by forces present in the apparatus 400. For example, the force transmitted from the camshaft 402 and the reaction force from the output device 403 may ensure that the link arm 428 and the transmitting element 424 remain in contact. At the contact interface between link arm 428 and transfer element 424, transfer element 424 may include a raised portion to provide rotational movement of transfer element 424 and reduce wear in the contact interface.

It is also possible to have the link arm 428 pivotally attached to the transfer element 424.

The second force transmitting element 406 may be arranged to be linearly displaced when the camshaft 402 rotates, to transmit a force to the output element 403. Thus, when the second force transfer element 406 alternately contacts the narrow and wide portions of the cam 408, the second force transfer element 406 is linearly displaced in a direction away from or toward the camshaft axis 426. The second force transmitting element 406 may be arranged to be linearly displaced towards the output device 403. In this way, the force may be efficiently transferred to the output device 403.

Similar to the contact portion 422 of the first transmission element, the second transmission element 406 may comprise a rolling element 435, the rolling element 435 being rotatable about the central axis 437 by means of a bearing. Thus, as the camshaft rotates, the rolling elements 435 rotate, thereby traveling along the outer circumference of the cam 408.

The first transfer element 404 may be mechanically coupled to the second force transfer element 406. Here, in fig. 4A-B, the transfer portion 424 of the first transfer element 404 is coupled to the coupling portion 431 of the second force transfer element 406. Thus, when the contact portion 422 of the first transfer element 404 is pushed away from the camshaft axis 426 by the cam 408, the transfer portion 424 rotates toward the side of the camshaft on which the second force transfer element 406 is located. As a result, the link arm 428 is pushed against the coupling portion 431. At the same time, the cam 408 causes the second transmission part 406 to be urged away from the camshaft axis 426 in a direction substantially opposite to the direction of movement of the first force transmitting element contacting part 422, and when the link arm 428 is urged by the transmission part 424, is urged away from the camshaft axis 426 in a direction substantially parallel to the direction of movement of the link arm 428. In this way, the forces transmitted by the force transmitting elements are synchronized. Furthermore, in this way, the first transmission element 404 and the second transmission element 406 are arranged such that the forces transmitted by the first transmission element 404 and the second transmission element 406 to the output device 403 add up to each other.

The link arm 428 may be pivotally attached to the coupling portion 431 or, as shown conceptually in fig. 4B, the link arm 428 may be placed in a cavity or bore 450 of the coupling portion in which the link arm 428 is guided and held in place so that it may push on the coupling portion 431. With the link arm 428 disposed in the cavity or bore 450, the link arm 428 does not have to be mechanically attached to the coupling portion 431.

The second transfer element 406, comprising the coupling part 431 and the rolling element 435, is held in place by a reaction force from the output 403, where the reaction force is provided by a spring 440. Thus, on one side of the second transmission element 406, the spring 440 exerts a force, and on the opposite side of the second transmission element 406, the link arm 428 and the cam 408 are arranged in contact with the second transmission element 406 to counteract the spring force. The spring 440 thus urges the second transfer element 406 toward the link arm 428 and the cam 408 such that the second transfer element 406 is held in place therebetween. The spring 440 maintains pressure on the second transmission element 406 such that it is urged toward the cam 408 of the camshaft 402 and maintains contact with the cam 408 of the camshaft 402. The force exerted by the spring 440 presses the second transmission element against the link arm 428 and the camshaft 402, the second transmission element 406 thus being suspended by the force exerted by the spring 440.

In addition, link arm 428 has a rounded front end 452 that fits in hole 450 or in some cases in a groove. The diameter of the hole 450 or groove is slightly larger than the diameter of the link arm 428 such that the link arm 428 is adapted to pivot in the hole 450 when the second force transmitting element 406 moves. This ensures smooth movement of the second transmission element when the link arm 428 exerts its force on the second transmission element 406 while the cam 408 exerts its force on the second transmission element 406.

The second transfer element 406 is preferably coupled to the output device 403, whereby the output device 403 pushes on the surface of the second transfer element 406, but the second transfer element and the output device are not mechanically attached to each other.

The link arm 428 applies its force to the second transfer element 406 at a distance from where the cam 408 applies the force to the rolling element 435. Thus, the aperture 450 is spaced from the rolling element 435. Furthermore, the output element 403 is arranged in contact with the second force transmitting element 406 at a position between the hole 450 and the rolling element 435 but on an opposite side of the second force transmitting element 406 with respect to the link arm 428 and the hole 450.

Preferably, and as shown in fig. 4A-B, the first transmission element 404 and the second transmission element 406 are arranged to be pushed by the same cam 408 on the camshaft 400. The cam 408 has lobes 432, 434 on opposite sides of the camshaft 402.

Preferably, the first and second transmission elements 404, 406 may be arranged to be pushed by a cam having a profile matching the position of the respective one of the first and second transmission elements 404, 406. In other words, the relative positions of the projections 432, 434 with respect to each other match the relative positions of the rolling element 435 of the second force transmission element and the rolling element 423 of the first force transmission element. Thus, when one of the projections 432, 434 contacts one of the rolling elements 435, 423, then the other of the projections 432, 434 contacts the other of the rolling elements 435, 423 at the widest portion having the width 412.

Force transfer apparatus 400 is housed in a housing that is attached to the engine at attachment hole 460. The housing defines a spacing 462 between the housing and the engine. The spacing between the housing and the engine is limited to prevent, for example, the second force transfer element from moving sideways, i.e. in or out of the plane of the figures in fig. 4A-B.

The output device 403 may be configured in various ways. Here, the spring 440 is arranged to provide a reaction force to the first and second transmission elements 404, 406 such that the first and second transmission elements remain in contact with the camshaft 400. The spring provides, for example, spring-loaded control of the fuel pump. The spring may for example be arranged in contact with a stop element 442, which stop element 442 is attached to a shaft 446 or coupled with the shaft 446, which shaft 446 is connected to the coupling portion 431 of the second transmission element 406. The shaft 446 transmits the forces from the first and second transmission elements to the fuel pump and is coaxially disposed within the spring 440. The shaft 446 is arranged in a through hole of the stop element 442, which stop element 442 may be provided in the form of a washer. The outer diameter of the washer is larger than the diameter of the spring 440 so that the spring can be pushed by the washer and prevented from falling out of the guide channel 448 leading to the fuel pump.

The output device 403 may be adapted to control a fuel pump or an oil pump. Embodiments of the present disclosure are advantageous for such devices because they tend to induce relatively high loads on the camshaft as compared to exemplary valves, which typically induce less loads.

There is also provided a vehicle engine including a camshaft, an output device, and a force transmitting apparatus according to an embodiment of the present disclosure.

Further, according to an aspect of the present disclosure, a vehicle including such a vehicle engine is provided.

The person skilled in the art realizes that the present invention by no means is limited to the preferred embodiments described above. On the contrary, many modifications and variations are possible within the scope of the appended claims.

The vehicle may be of various types, for example a light vehicle such as a car, although a truck may also be suitable.

In the claims, the word "comprising" does not exclude other elements or steps, and the indefinite article "a" or "an" does not exclude a plurality. A single processor or other unit may fulfill the functions of several items recited in the claims. The mere fact that certain measures are recited in mutually different dependent claims does not indicate that a combination of these measures cannot be used to advantage. Any reference signs in the claims shall not be construed as limiting the scope.

Various examples have been described. These and other examples are within the scope of the following claims.