Source: https://patents.google.com/patent/JP4420826B2/en
Timestamp: 2020-05-29 05:08:22
Document Index: 679029525

Matched Legal Cases: ['art 15', 'art 15', 'art 21', 'art 21', 'arts 15', 'art 21', 'art 21', 'art 21', 'art 21', 'art 15', 'art 15', 'art 15']

JP4420826B2 - 2-arm belt tensioner for belt drive - Google Patents
2-arm belt tensioner for belt drive Download PDF
JP4420826B2
JP4420826B2 JP2004563253A JP2004563253A JP4420826B2 JP 4420826 B2 JP4420826 B2 JP 4420826B2 JP 2004563253 A JP2004563253 A JP 2004563253A JP 2004563253 A JP2004563253 A JP 2004563253A JP 4420826 B2 JP4420826 B2 JP 4420826B2
JP2004563253A
JP2006512544A (en
ダミカントーニオ，ルーカ
ロッリ，セルジョ
ダイコ ユーロペ ソシエタ ア レスポンサビリタ リミタータ コン ユニコ ソシオ
2003-12-29 Application filed by ダイコ ユーロペ ソシエタ ア レスポンサビリタ リミタータ コン ユニコ ソシオ filed Critical ダイコ ユーロペ ソシエタ ア レスポンサビリタ リミタータ コン ユニコ ソシオ
2006-04-13 Publication of JP2006512544A publication Critical patent/JP2006512544A/en
2010-02-24 Publication of JP4420826B2 publication Critical patent/JP4420826B2/en
The present invention relates to a belt tensioner for a belt drive of an internal combustion engine, and more particularly, to a two-arm belt tensioner for an auxiliary belt drive for connecting an engine shaft of an internal combustion engine to an electric machine capable of rotating in reverse.
As is known, the current trend of automakers is to replace conventional starter motors and generators with a single counter-rotatable electric machine connected to the engine shaft by a drive belt. During the start-up phase, the counter-rotatable electric machine functions as a motor and drives the engine shaft of the internal combustion engine. When the vehicle is moving, the electric machine is instead driven by an internal combustion engine to generate a battery charging current.
The belt connecting the electric machine to the engine shaft of the internal combustion engine can be used to drive one or more further auxiliary members, for example air conditioning compressors.
As is known, belt drives typically have a belt tensioner, i.e. a device comprising an idle pulley attached to a movable arm that is spring loaded in the direction of the belt to compensate for changes in the tension of the belt itself. Are associated. The belt tensioner acts on the loose part of the belt, i.e. the part that is not very tensioned, which is located downstream of the drive pulley with respect to the direction of movement.
When a counter-rotatable electric machine having the functions of a starter motor and a current generator is used, the belt portion has a different tension depending on the operation mode. That is, the portion to which tension is applied during the start-up stage in which the electric machine is the driving member and the internal combustion engine is the driven member is loosened in the normal operation stage in which the internal combustion engine is the driving member and the electric machine is the driven member.
In order to overcome this problem, bidirectional belt tensioners or two-arm belt tensioners have been proposed, i.e. including two arms with pulleys each acting against a respective arm of the belt. The two arms rotate about a common axis and are loaded in the direction of each other by a spring so that each pulley cooperates with each part of the belt and ensures that they are tensioned Can be attached to other pins.
Patent Document 1 discloses a fixed portion, first and second arms that are hingedly connected to a fixed position with respect to a common shaft and carry respective idle pulleys, and the pulleys in contact with respective branches of the transmission belt. A belt tensioner is disclosed that includes a spring that biases the arms toward each other to be held together.
Stop means are provided to limit the progress of each arm in the direction of the spring force to determine the assembly position of the arm and in the opposite direction to prevent over travel of the arm under dynamic belt tension variations. It is done.
International Publication No. 00/77422 Pamphlet
The present invention aims to provide an improved tensioner of the kind described above, which has a simplified structure, in particular with respect to the fixing part.
The purpose is to have a fixed part (21) designed to be fixed to the support structure (22), and a hinged part carried by the fixed part (21) around the common axis (A) to the fixed part (21). The belt (15 ) of the belt drive (1) attached with play to the connected first arm (23) and second arm (24) and the respective ends (60, 61) of the arms (23, 24). The first pulley (25) and the second pulley (26) designed to cooperate with the respective parts (15a, 15b) of the belt (15) and the pulleys (25, 26) respectively. Two-arm type for the belt drive (1) , comprising elastic means (27) forcing the arms (23, 24) to face each other so as to keep them in contact with the parts (15a, 15b) Belt tensioner Te, said arms (23, 24) interacts with said fixed part (21) so as to define a first position of each of the restraining of the arm (23, 24) under the action of said elastic means (27) A respective first restraining element (37, 47) designed in such a way that each second position at the end of the stroke of the arm (23, 24) under the action of the respective tension of the belt (15) Each of the second restraining elements (38, 39; 48, 49) designed to interact with the fixing part (21) to define a base plate (30). And a pin (31) that is fixed to the plate (30) and defines the common axis (A) of rotation of the two arms (23, 24). The belt tensioner includes the fixing portion (21). Fixed to the base plate (30) It said first and second restraining elements of the serial arm (23, 24) viewed including the appendage (32) defining a contact element of the (37, 47; 38, 39 48, 49) for the first The angular position of the restraining elements (37, 47) is achieved by means of a belt tensioner, characterized in that the pulleys (25, 26) are defined so as to be close to each other but not in contact with each other .
For a better understanding of the present invention, the following preferred embodiments will be described with reference to the accompanying drawings, given solely by way of non-limiting examples. Referring to FIG. 1, a belt drive for an internal combustion engine 2 of an automobile is indicated by a reference numeral 1 as a whole. The belt drive 1 includes an electric machine 4 capable of rotating in reverse and an engine (with an auxiliary member 5 such as an air-conditioning compressor). Engine) 2 is connected to the engine shaft 6.
More specifically, the drive 1 is fixed to the first pulley 7 fixed to the engine shaft 6, the second pulley 8 fixed to the shaft 9 of the electric machine 4, and the shaft 11 of the auxiliary member 5. And a third pulley 10. The drive 1 is wound around the pulleys 7, 8, and 10, so the first portion 15a between the pulley 7 and the pulley 8, the second portion 15b between the pulley 8 and the pulley 10, and the pulley And a belt (15) having a third portion 15c between the pulley 10 and the pulley 7.
As before, the belt 15 is of the poly V type and the pulleys 7, 8 and 10 have corresponding working contours with a number of guide grooves (not shown).
The direction of rotation of the engine shaft is clockwise as shown in FIG.
The electric machine 4 can operate in two different modes of operation, as is known per se. During normal operation, the electric machine 4 is driven by the engine 2 by the belt 15 and operates as a current generator. In the starting transient, instead, the electric machine 4 absorbs power and acts as a drive member. In the latter mode of operation, the engine shaft 6 is mechanically driven by the belt 15.
According to the mode of operation, in particular with the drive member, the distribution of tension changes varies in various parts of the belt 15. In particular, during normal operation, the tension in the second part 15b ("tensioned part") is considerably higher than the tension in the first part 15a ("relaxed part"), while starting, The first portion 15a is tensioned and the second portion 15b is loose.
Finally, the drive 1 has a two-armed belt tensioner 20 that cooperates with the belt 15 to ensure the correct tension at each operating condition.
The belt tensioner 20 (FIGS. 2 to 4) is a fixed part 21 designed to be fixed to a fixed support structure 22, i.e. a bracket fixed to the engine 2 in the region inside the belt 15, for example, A first part comprising a part of the engine block and a respective idle pulley 25, 26 hingedly fixed to the fixing part 21 around a common axis A and cooperating with the parts 15a and 15b of the belt 15 respectively. The arm 23 and the second arm 24 are included.
More specifically, the arms 23, 24 are loaded in the direction of each other by a spring 27, which is conveniently helical, and the pulley cooperates with the outer surface of each portion 15a, 15b of the belt 15.
The elastic characteristic of the spring 27 is such that the return torque applied to the arm 23 or 24 by the tension of the belt 15 is lower than the torque applied to the arm itself by pulling the belt 15 under the operating conditions. Selected.
The structure of the belt tensioner will be described in detail below with reference to FIGS. 3 and 5 in particular.
The fixing part 21 has a base plate or disk 30 to which a tubular axial pin of the axis A is firmly fixed. Extending radially from the disk 30 is a generally L-shaped appendage 32 that functions as a restraining element for the arms 23, 24, as described in detail below.
The two arms 23, 24 are hingedly connected to the pin 31, and a radial friction preventing bushing 33 is inserted between them. More specifically, the arm 23 comprises a hub 34 having a substantially circular end, one of its faces having a protruding circumferential direction designed to surround the disk 30 of the fixed part 21 in use. It has an edge 35. The edge 35 has a break or opening 36 in a position opposite to the main extension direction of the arm 23 that engages the appendage 32 during use. One end of the opening 36 (FIGS. 5 and 6) is for the arm 23 under the action of a spring 27 (which tends to rotate the arm 23 clockwise as shown in FIGS. 5-7). Are designed to cooperate with the appendage 32 to define the angularly constrained contrast element 37. In the vicinity of the opposite end (not shown) of the opening 36, a projection 38 with a buffer 39 made of an elastomeric material that extends in the circumferential direction and faces the appendage 32 extends radially. In use, the arm 23 is attached to the fixture so that the appendage 32 exits radially through the opening 36. Thus, the arm 23 has a first restrictive position determined by contact between the appendages 32 and a first position determined by contact between the protrusion 38 (or its associated buffer 39) and the appendages 32 under the tension of the belt 15. It rotates freely with respect to the fixed part between the two limit positions.
The hub 34 of the arm 23 can further rotate on the bushing 33 on the opposite side of the edge 35 in the axial direction to withstand moments that cause turnover and the inner end 44 of the spring 27. Completely defines an axial tubular sleeve 43 having the dual purpose of providing a tether for the purpose.
The arm 24 includes a generally cup-shaped end hub 45 that is hingedly connected to the bushing 33 and forms an annular cavity with the hub 34 of the arm 23, and the annular cavity is a piece from the arm 24 toward the arm 23. It is constrained radially by a cylindrical wall 46 that extends axially in a cantilevered manner. The wall 46 defines a tether for the outer end 40 of the spring 27 (FIG. 6).
Extending cantilevered from the wall 46 are two radial projections 47, 48 that, in use, are placed on opposite sides of the fixture appendage 32 to define respective restraints of the arm 24. . In particular, the protrusion 47 is designed to form a restraint for the arm 24 under the action of a spring 27 that rotates the arm 24 counterclockwise as shown in FIGS. 3 and 5-7. The protrusion 48 comprises a buffer 49 formed from an elastomeric material designed to contact the appendage 32 at the position of maximum rotation (in the clockwise direction) of the arm 24 under the tension of the belt 15.
Thus, the arm 24 is free with respect to the protrusions 47 and the fixed portion 21 between the two restricted positions defined by contact of the protrusions 48 (or the buffers 49 associated therewith) to the appendages 32, respectively. Rotate.
The belt tensioner 20 is further placed axially between the arm 23 on the one hand and the spring 27 and the arm 24 on the other hand so as to reduce the relative friction between the two arms 23, 24 as much as possible. A friction preventing ring 50 is further provided.
The fixing part 21 of the belt tensioner 20 is in a known manner by a ring 53 for axial blocking which is fixed to the free end of the pin 31 by its plastic deformation, and also for example a plastic which is polyamide 4,6. Annular, made of material, one disposed between the disk 30 and arm 23 of the fixed part 21 and the other axially disposed between the arm 24 and the blocking ring 53 to define the damping characteristics of the arm vibration Completed by a pair of elements 54,55. A Belleville spring 56 placed between the arm 24 and the annular element 55 maintains the assembly under axial tension and restores any play.
The pulleys 25, 26 are attached to the free ends 60, 61 of the arms 23, 24 by respective bearings (not shown) with play and rotate freely about the respective axes B and C.
The belt tensioner 20 is attached to the support structure 22 by a single screw 62 that passes through the pin 31. Desirably, the fixed portion disk 30 has teeth (not shown) designed to engage corresponding seats of the fixed structure 22 to prevent rotation of the fixed portion 20 about axis A in a known manner. Have.
The operation of the belt tensioner 20 will be described below.
The belt tensioner 20 is in the state shown in FIG. 6 before being assembled and installed in the engine. The action of the spring 27 that loads the two arms 23, 24 in the direction relative to each other keeps the arms themselves in the respective positions of the protrusions relative to the appendages 32, as defined by the contact of the contrast element 37. The position of the arms 23, 24 is thus uniquely determined, which facilitates general packaging and handling of the belt tensioner 20 prior to engine installation. The angular position of the contrast element 37 and of the projection 47 is defined such that the two pulleys 25, 26 are close to each other but not in contact with each other.
Once the belt tensioner 20 is attached to the fixed structure 22 with the screw 62, after installing the belt 15 on the engine 2, the arms 23, 24 are moved so that the pulleys 25, 26 are outside the respective portions 15a, 15b of the belt 15. It is sufficient to unfold (obviously, this is only possible by shifting the belt laterally to allow the pulleys to pass).
After this action, the arms 23, 24 are placed in a rest position defined by the balance between the tension of the belt 15 and the return force of the spring 27 (FIG. 2).
At startup, the electric machine 4 functions as a motor, and drives the engine shaft 6 of the internal combustion engine 2 by the belt drive 1. Accordingly, the portion 15 a is a portion to which the belt 15 is tensioned, and the tension of the belt 15 in the portion overcomes the return force of the spring 27, and causes the arm 23 to move the protrusion 38 against the appendage 32. It is sent to the position of restraint defined by the contact of the buffer 39 (see FIG. 8). The buffer 39 has a function of reducing contact noise.
In the state described above, the pulley 25 of the arm 23 behaves like a fixed idler pulley or idler. The arm 24 acting against the loose portion 15b instead operates as a conventional single arm belt tensioner and dynamically cooperates with that portion by means of a pulley 26, thus compensating for variations in its tension. .
Once the predetermined threshold of the speed of the engine shaft 6 is reached, the engine is supplied and moved from the driven state to the ignition or ignition state. The part 15c is here of the maximum tension of the belt, but the part 15b is also a tensioned part (considering the relatively reduced elastic torque of the auxiliary member 5), while the part 15a The tension is quite low (loose part). In this operating state, the arm 24 is fed to the end of the tension stroke of the belt 15 and stops as a result of the contact of the buffer 49 of the protrusion 48 with the appendage 32 (see FIG. 7). The arm thus operates like an idler. Instead, the arm 23 acting as a loose portion 15a acts as a conventional single arm belt tensioner and dynamically cooperates with that portion by means of a pulley 25, thus compensating for variations in its tension.
By examining the characteristics of the belt tensioner 20 constructed according to the present invention, the advantages made possible by this are clear. In particular, the belt tensioner 20 has an integrated restraining element that defines the position of movement of the arms 23, 24, both of which are in an operational state prior to installation. Therefore, the belt tensioner 20 is particularly simple and inexpensive to manufacture, is small in size, easy to install and handle before installation on the engine, and is convenient to install on the engine.
Finally, it will be apparent from the foregoing description that modifications and changes may be made to the belt tensioner 20 described herein without departing from the scope of the appended claims.
It is a front view which shows the belt drive for internal combustion engines provided with the 2 arm type belt tensioner constructed | assembled by this invention. FIG. 2 is a front view showing the belt tensioner shown in FIG. 1 in a state where a drive is stationary at an engine installation position. It is sectional drawing by line III-III of FIG. FIG. 3 is a side view according to a direction X in FIG. 2. It is a disassembled perspective view of a belt tensioner. It is a front view which shows the belt tensioner shown in FIG. 1 in the state of the assembly before installation to an engine. It is a figure which shows the front view of a belt tensioner in the one operation position corresponding to each drive mode of a drive. It is a figure which shows the front view of a belt tensioner in the other operation position corresponding to each drive mode of a drive.
A fixing part (21) designed to be fixed to the support structure (22); and a first part carried by the fixing part (21) and hingedly connected to the fixing part (21) around a common axis (A). 1 arm (23) and second arm (24), and each end (60, 61) of said arm (23, 24) is attached with play to each of belt (15) of belt drive (1) . A first pulley (25) and a second pulley (26) designed to cooperate with the parts (15a, 15b) and the pulleys (25, 26) are connected to the respective parts (15a 15b) with a resilient means (27) forcing the arms (23, 24) to face each other so as to keep them in contact with each other, a two-arm belt tensioner for the belt drive (1) . And
The arms (23, 24) are designed to interact with the fixed part (21) so as to define respective first positions of the restraints of the arms (23, 24) under the action of the elastic means (27). And a respective second position at the end of the stroke of the arm (23, 24) under the action of the respective pulling of the respective first restraining element (37, 47) and of the belt (15). Each of the second restraining elements (38, 39; 48, 49) designed to interact with said securing part (21),
The fixing portion (21) includes a base plate (30) and a pin (31) fixed to the plate (30) and defining the common axis (A) of rotation of the two arms (23, 24), In the belt tensioner, the fixing portion (21) is fixed to the base plate (30), and the first and second restraining elements ( 37, 47; 38, 39; 48, 49) of the arms (23, 24). ) seen containing an appendage (32) defining a contact element for the angular position of the first constraining element (37, 47), said pulleys (25, 26), but are close to each other do not contact each other A belt tensioner characterized by being defined as follows .
At least one of the first and second restraining elements ( 37, 47; 38, 39; 48, 49) of the arms (23, 24) extends from the respective arms (23, 24), and 2. A belt tensioner according to claim 1, characterized in that it has radial projections (47, 38, 48) designed to interact with the appendages (32) of the fastening part (21).
At least one of the arms (23, 24) has a hub (34), the hub (34) at least partially containing the base plate (30) through which the appendage (32) passes. In which at least one of the restraining elements (37 , 47; 38, 39; 48, 49 ) is defined by an end that delimits the opening (36). The belt tensioner according to claim 2.
The second restraining elements (38, 39; 48, 49) include respective buffers (39, 49) formed of an elastic material that absorbs an impact with the fixing portion (21). The belt tensioner according to any one of claims 1 to 3.
The elastic means has a spiral spring (27), and one of the arms (24) has a cup-shaped hub (45) for accommodating the spring (27), The hub (45) houses the spring (27), which is restrained to the hub (45) by its own outer end (40) and the other arm by its own inner end (44). The belt tensioner according to any one of claims 1 to 4, wherein the belt tensioner is restrained by (23).
A belt drive (1) for connecting a reverse-rotatable electric machine (4) to an engine shaft (6) of an internal combustion engine (2), the electric machine (4) being an electric for starting the internal combustion engine (2) Can operate as a machine or as a generator,
The belt drive (1)
At least one first pulley (7) fitted in the engine shaft (6) of the internal combustion engine (2);
A second pulley (8) fitted in the shaft (9) of the electric machine (4);
Wound around the pulleys (7, 8), between the first pulley (7) and the second pulley (8), and between the second pulley (8) and the first pulley A belt (15) having a first part (15a) and a second part (15b) respectively placed between (7) in the direction of movement of the belt (15) itself;
A fixing part (21) designed to be fixed to the support structure (22) and a first arm (23) carried by said fixing part ( 21 ) and hingedly connected thereto with respect to a common axis (A) ) And the second arm (24) and the respective ends (60, 61) of the arms (23, 24) with play, and the first part (15a) of the belt (15) and The first pulley (25) and the second pulley (26) designed to cooperate with the second part (15b), respectively, and the arm (23, 24) are connected to the pulley (25, 26). A two-arm belt tensioner (20) having elastic means (27) forcing them to face each other to maintain contact with the respective parts (15a, 15b) of the belt (15) ,
The arms (23, 24) interact with the fixing part (21) so as to define respective first positions of restraints of the arms (23, 24) under the action of the elastic means (27). Each designed first restraining element (37, 47) and a respective second position at the end of the stroke of the arm (23, 24) under the action of the tension of the belt (15). Each second restraining element (38, 39; 48, 49) designed to interact with said securing part (21);
The fixing portion (21) includes a base plate (30) and a pin (31) fixed to the plate (30) and defining the common axis (A) of rotation of the two arms (23, 24), In the belt drive (1) , the fixing portion (21) is fixed to the base plate (30), and the first and second restraining elements ( 37, 47; 38, 39) of the arms (23, 24); 48, 49) appendage defining a contact element for (32) only containing the angular position of the first constraining element (37, 47), said pulleys (25, 26), but are close to each other A belt tensioner , characterized in that it is defined not to contact each other .
The elastic means (27) causes the rotation of the arms (23, 24) of the tensioner (20) to their respective second restraining positions when there is a maximum tension in the respective part of the belt. 7. The belt tensioner according to claim 6, wherein the rigidity is calculated.
JP2004563253A 2002-12-30 2003-12-29 2-arm belt tensioner for belt drive Expired - Fee Related JP4420826B2 (en)
JP2006512544A JP2006512544A (en) 2006-04-13
JP4420826B2 true JP4420826B2 (en) 2010-02-24
JP2004563253A Expired - Fee Related JP4420826B2 (en) 2002-12-30 2003-12-29 2-arm belt tensioner for belt drive
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ES2295214T3 (en) * 2000-10-03 2008-04-16 The Gates Corporation Accessories and motor / generator belt drive tensioner.
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