JP2004198259A - A/t tester - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an automatic transmission (A/T) tester which can check for effect on A/T under the vibrations generated by the operation of the engine in the performance test of the A/T. <P>SOLUTION: An A/T tester 1 which carries out the performance test of an A/T 7 has an input motor 2 for reproducing the rotation by the combustion of the engine simulatively, an output motor 3 for reproducing the load working on an output shaft 73 of the A/T 7 simulatively, an input side support part 4 for supporting a housing 71 of the A/T 7 and an output side support part 5 for maintaining the attitude of the A/T 7. The input motor 2 and an input connection shaft 42 and the output motor 3 and an output connection shaft 52 are connected together respectively being allowed to be decentered from each other with respective constant velocity joints 61 and 62. Dampers 65 and 66 are disposed respectively between the input side support part 4 and an input side fixed surface 814 and between an output side support part 5 and an output side fixed surface 121. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
【Technical field】
The present invention relates to an automatic transmission (A / T) test apparatus for performing a performance test of an automatic transmission (A / T).
[0002]
[Prior art]
When performing a performance test of the automatic transmission (A / T), as shown in FIG. 5, a load applied to an input motor 92 for simulating the rotation of the engine and a load applied to an output shaft 73 of the A / T 7 are simulated. An A / T test apparatus 9 having an output motor 93 for reproducing the same is used. A housing 71 of the A / T 7 is fixed to the A / T test apparatus 9 by a fixing portion 94, and the input motor 92 is connected to the input shaft 72 of the A / T 7 and the output shaft 73 of the A / T 7 is connected to the A / T 7 output shaft 73. The output motor 93 is connected. In this state, the input motor 92 is rotated at a desired torque and rotation speed, and a performance test such as a shift operation of the A / T 7 is performed. Examples of such an A / T test apparatus 9 or A / T test method include those shown in Patent Documents 1 and 2.
[0003]
[Patent Document 1]
JP 2001-165282 A [Patent Document 2]
JP 2000-258303 A
[Problem to be solved]
However, in the above-described conventional A / T test apparatus 9, the performance test is performed with the housing 71 of the A / T 7 fixed to the A / T test apparatus 9. For this reason, even if an attempt is made to give the A / T 7 to be tested a vibration which is assumed when the A / T 7 is mounted on an actual vehicle, the whole device becomes a resistance and cannot do so.
For this reason, it is difficult for the conventional A / T test apparatus 9 to confirm the effect of the A / T 7 on the vibration caused by the input motor 92 or the vibration from the road surface when the vehicle is running.
[0005]
The present invention has been made in view of such a conventional problem. In an A / T performance test, the A / T can be vibrated positively, and the influence of the vibration on the A / T is confirmed. It is intended to provide an A / T test apparatus that can perform the test.
[0006]
[Means for solving the problem]
The present invention relates to an A / T test apparatus for performing a performance test of an automatic transmission (hereinafter referred to as A / T).
The A / T test device includes an input motor for simulating the rotation of a vehicle driving engine,
An output motor for simulating the load applied to the A / T output shaft;
An input connection shaft connected to the input shaft of the A / T, and an input-side support portion for supporting the housing of the A / T;
An output-side support portion having an output connection shaft connected to the A / T output shaft;
The input motor and the input connection shaft, and the output motor and the output connection shaft are connected to each other by a constant velocity joint so as to be eccentric to each other, and are connected to the input side support portion and the output side support portion. An A / T test apparatus is characterized in that dampers for enabling these to swing are respectively provided between a fixed surface on which these are arranged, and an A / T test apparatus (claim 1).
[0007]
The A / T test apparatus of the present invention has constant velocity joints for connecting the input motor and the input connection shaft of the input side support, and the output motor and the output connection shaft of the output side support, respectively. And each of the dampers is provided between the input side support portion and the output side support portion and the fixing surface. Therefore, each constant velocity joint allows the input connection shaft and the output connection shaft to be eccentric with respect to the input motor and the output motor, respectively. Further, the input-side support portion and the output-side support portion are swingably held by each damper.
[0008]
The A / T test is performed by mounting the A / T on the housing on the input side support portion, connecting the input shaft to the input connection shaft, and connecting the output shaft to the output connection shaft. When the A / T is set in the apparatus, the A / T is set in a state where it can vibrate almost freely without much resistance from other parts due to the existence of the constant velocity joints and the dampers.
[0009]
When performing a performance test with the A / T set, the input motor is rotated so as to simulate the rotation caused by the operation of the vehicle drive engine. At this time, the A / T means that the input shaft rotates through the constant velocity joint and the input connection shaft, and the output shaft has the moment of inertia of the output motor through the output connection shaft and the constant velocity joint. Rotate while working.
[0010]
If, for example, vibration from the road surface or vibration from the input motor is positively applied to the A / T as described later, the A / T receives the vibration faithfully and vibrates itself. You can continue rotating while doing.
Therefore, according to the A / T test apparatus, it is possible to perform a performance test while actively and effectively transmitting various vibrations whose effects are to be investigated to the A / T. Further, according to the A / T test apparatus, it is possible to confirm the influence of the various vibrations on the A / T.
[0011]
In the above performance test, for example, when vibration occurs in the A / T, an oil leak confirmation test for confirming whether or not an oil leak occurs in the A / T, or no abnormal noise occurs in the A / T. A performance test such as an abnormal sound confirmation test for confirming the above can also be performed.
[0012]
BEST MODE FOR CARRYING OUT THE INVENTION
A preferred embodiment of the present invention described above will be described.
In the present invention, examples of a vehicle driving engine in which the input motor attempts to reproduce rotation include an engine that performs a combustion operation, an electric motor that is used in an electric vehicle, a hybrid car, and the like.
Further, as the above-mentioned damper, for example, there is a damper configured by using an elastically deformable material such as rubber or a spring, or a damper having a repulsive force such as a cylinder or a gas cushion and capable of reciprocating.
[0013]
The A / T test device has a vibration device for simulating vibration transmitted from the road surface to the A / T, and includes at least one of the input-side support portion and the output-side support portion. Is preferably disposed on the vibration device via the damper (claim 2).
[0014]
In this case, the A / T can be directly vibrated by the vibration device, and vibration (vehicle vibration) transmitted from the road surface to the A / T can be given. Therefore, by using the vibration device, in the performance test, it is possible to confirm the influence of the vibration transmitted from the road surface on the vehicle equipped with the A / T on the A / T.
[0015]
Further, it is preferable that the input motor is configured to generate a periodically fluctuating torque in order to reproduce the vibration from the vehicle driving engine in a pseudo manner.
In this case, the input motor can form a rotational state that is as close as possible to the rotational state of the engine that performs the combustion operation. Therefore, in the performance test using the A / T test apparatus, it is possible to confirm the influence of the vibration generated by the fluctuation torque on the A / T.
[0016]
【Example】
Hereinafter, embodiments of the A / T test apparatus of the present invention will be described with reference to the drawings.
The A / T test apparatus 1 of the present embodiment is for performing a performance test of an automatic transmission 7 (hereinafter, referred to as A / T7) as shown in FIGS. The A / T test apparatus 1 includes an input motor 2 for simulating the rotation of a vehicle driving engine and an output motor 3 for simulating a load applied to an output shaft 73 of the A / T 7. And
[0017]
Further, the A / T test apparatus 1 has an input-side support section 4 for supporting the housing 71 of the A / T 7 and an output-side support section 5 for maintaining the attitude of the A / T 7. The input-side support section 4 includes an input connection shaft 42 connected to the input shaft 72 of the A / T 7, and the input-side support section 4 includes an output connection shaft connected to the output shaft 73 of the A / T 7. 52 are provided.
[0018]
The input motor 2 and the input connection shaft 42 are connected by an input side constant velocity joint 61 so as to be eccentric to each other. The output motor 3 and the output connection shaft 52 are connected by an output-side constant velocity joint 62 so as to be eccentric to each other.
An input-side damper 65 is provided between the input-side support portion 4 and the input-side fixing surface 814 on which the input-side support portion 4 is arranged so that the input-side support portion 4 can swing. An output-side damper 66 is provided between the output-side support portion 5 and the output-side fixing surface 121 on which the output-side support portion 5 is provided so that the output-side support portion 5 can swing.
[0019]
The details are described below.
As shown in FIG. 3, the input motor 2 is configured to generate periodically fluctuating torque in order to simulate the vibration from the vehicle driving engine. This fluctuating torque can be generated by configuring the input motor 2 with a servomotor and performing torque control of the servomotor.
In addition, the above-mentioned fluctuating torque is generated to reproduce torque generated by an engine such as an internal combustion engine that performs a combustion operation.
[0020]
As shown in FIG. 4, the output motor 3 electrically generates a moment of inertia to simulate a load applied to the output shaft 73 of the A / T 7. The load caused by the output motor 3 includes the moment of inertia generated from the output shaft 73 of the A / T 7 to the drive wheels via the propeller shaft, the drive shaft, etc., and the rolling friction resistance generated between the drive wheels and the road surface in the vehicle. It is set in consideration of.
[0021]
As shown in FIGS. 3 and 4, each of the constant velocity joints 61 and 62 is formed by two joint portions 632 and a shaft portion 631 connecting these joint portions. In each of the constant velocity joints 61 and 62, the axis of each joint 632 can be decentered by tilting the shaft 631 while keeping the axial direction of the two joints 632 parallel.
Although not shown, each of the constant velocity joints 61 and 62 has a plurality of balls and the rolling of the plurality of balls between the joints 632 and both ends of the shaft 631, respectively. This is a constant velocity ball joint including a bearing member having a guide groove for guiding in a direction.
[0022]
As shown in FIG. 3, in the A / T test apparatus 1, the input-side support portion 4 tilts the shaft portion 631 of the input-side constant velocity joint 61 obliquely, thereby forming the input connection shaft 42. In a state where the axial direction is aligned with the axial direction of the input motor 2, the input motor 2 can swing in a cross-sectional direction orthogonal to the axial direction.
As shown in FIG. 4, the output-side support portion 5 tilts the shaft portion 631 of the output-side constant velocity joint 62 obliquely so that the axial direction of the output connection shaft 52 becomes the axis of the output motor 3. In a state aligned with the direction, it can swing in a cross-sectional direction orthogonal to the axial direction.
[0023]
As shown in FIG. 3, the input-side support portion 4 fixes the A / T 7 to the main body 41, the input connection shaft 42 rotatably supported by the main body 41, and the main body 41. And a fixing portion 43 for the connection. In this example, the flange portion 711 located on the input shaft 72 side of the housing 71 of the A / T 7 is fixed to the main body portion 41 by the fixing portion 43. The input connection shaft 42 has a connection portion 421 (see FIG. 2) for connecting the input shaft 72 of the A / T 7.
[0024]
The A / T test apparatus 1 has a vibration device 81 for simulating the vibration transmitted from the road surface to the A / T 7. The input-side support 4 is disposed on the vibration device 81 via the input-side damper 65. The input-side damper 65 of this example is a vibration-proof rubber as a vibration-proof material that can be elastically deformed.
[0025]
As shown in the figure, the vibration device 81 is configured using a cylinder 811 and generates vibration by reciprocating a rod portion 812 that is a movable portion of the cylinder 811. The vibration device 81 of this example is configured to generate a vertical vibration by servo-controlling a plurality of hydraulic cylinders 811.
Each hydraulic cylinder 811 is fixed to the base stand 11, and a rod 812 of each hydraulic cylinder 811 is attached to a vibration plate 813. The input-side damper 65 is disposed between the main body 41 of the input-side support 4 and the vibration plate 813. Note that the input-side fixed surface 814 of this example is the upper surface 814 of the vibration plate 813.
[0026]
As shown in FIG. 4, the output-side support section 5 has a main body section 51 and the output connection shaft 52 rotatably supported by the main body section 51. It has a connection portion 521 for connecting the output shaft 73 of the A / T 7.
Further, between the output side constant velocity joint 62 and the output motor 3, a torque measuring device 82 capable of measuring a load torque applied to the output shaft 73 of the A / T 7 and a moment of inertia by the output motor 3 are provided. A brake device 83 that can adjust the load and give a load change to the output shaft 73 of the A / T 7 due to the braking operation of the vehicle is provided.
[0027]
The output side constant velocity joint 62 and the output motor 3 are connected by a relay shaft 84, and a torque measuring device 82 and a brake device 83 are provided for the relay shaft 84, respectively.
Further, by using the torque measuring device 82 and the brake device 83, the moment of inertia generated by the output motor 3 can be controlled.
[0028]
As shown in the figure, the A / T test apparatus 1 has a slide base 12 for sliding the output-side support portion 5 in the axial direction with respect to the base gantry 11. The output-side support section 5 is disposed on the slide base 12 via the output-side damper 66. Further, the output side damper 66 of this example is a spring, and the output side fixed surface 121 is the upper surface 121 of the slide base 12.
The output motor 3, the torque measuring device 82 and the brake device 83 are also provided on the slide base 12, and all the devices mounted on the output shaft 73 side of the A / T 7 are controlled by the slide base 12. It is movable in the axial direction.
[0029]
As described above, the axis of the input connection shaft 42 can be eccentric with respect to the axis of the input motor 2 by the input-side constant velocity joint 61. Further, the input-side support section 4 can be swung in a cross-sectional direction orthogonal to the axial direction of the input motor 2 by the input-side damper 65.
Further, the axis of the output connection shaft 52 can be decentered with respect to the axis of the output motor 3 by the output side constant velocity joint 62. Further, the output-side support section 5 is swingable in the transverse section direction orthogonal to the axial direction of the output motor 3 by the output-side damper 66.
[0030]
Then, as shown in FIGS. 2 and 3, when performing the performance test in the A / T test apparatus 1, the A / T 7 to be tested is attached to the input-side support unit 4. Then, the input shaft 72 of the A / T 7 is connected to the input connection shaft 42 of the input side support portion 4, and the housing 71 of the A / T 7 is fixed to the input side support portion 4 by the fixing portion 43.
[0031]
Next, as shown in FIG. 1, the slide base 12 on which the output-side support portion 5 and the output motor 3 are disposed is slid, and the output shaft 73 of the A / T 7 is connected to the output connection shaft of the output-side support portion 5. 52. Thus, the A / T 7 can be set in the A / T test apparatus 1.
When the output shaft 73 of the A / T 7 is connected to the output connection shaft 52 of the output-side support portion 5, as shown in FIG. 4, the positioning provided between the output-side support portion 5 and the slide base 12 is performed. The cylinder 85 allows the axis of the output connection shaft 52 to be aligned with the axis of the output shaft 73 of the A / T 7.
[0032]
As shown in FIG. 1, in the A / T test apparatus 1 of the present embodiment, the set A / T 7 is connected to the input motor 2 and the output motor 3 via the constant velocity joints 61 and 62. ing. Therefore, the A / T 7 can be eccentric with respect to the axis of the input motor 2 and the output motor 3 by the constant velocity joints 61 and 62.
The set A / T 7 is set in the A / T test apparatus 1 via the dampers 65 and 66. Therefore, the A / T 7 can be swung by the respective dampers 65 and 66 in the cross-sectional direction orthogonal to the axial direction.
As described above, the A / T set in the A / T test apparatus vibrates almost freely due to the presence of the constant velocity joints 61 and 62 and the dampers 63 and 64 without receiving much resistance of other parts. You can do it.
[0033]
When the A / T 7 is set, the rotation of the input motor 2 is controlled to fluctuate the torque generated by the input motor 2 in order to simulate the rotation caused by the combustion of the engine. . At this time, the A / T 7 has its input shaft 72 rotating via the input side constant velocity joint 61 and the input connection shaft 42, and its output shaft 73 has the output connection shaft 52 and the output side constant velocity joint 62. And, it rotates with the moment of inertia by the output motor 3 acting via the relay shaft 84.
[0034]
When vibration occurs due to the rotation of the input motor 2 accompanied by the torque fluctuation, the A / T 7 faithfully reproduces the vibration due to the presence of the constant velocity joints 61 and 62 and the dampers 65 and 66. And continue to rotate while vibrating.
In addition, when the vibration device 81 is operated, the A / T 7 can be provided with vibration (vehicle vibration) transmitted from the road surface to the A / T 7 when the vehicle is mounted. Therefore, also in this case, the A / T 7 can receive the vibration of the vehicle faithfully and continue rotating while vibrating by itself.
[0035]
Therefore, according to the A / T test apparatus 1, a performance test can be performed while actively and effectively transmitting the vibration accompanying the fluctuation torque of the engine and the vibration transmitted from the road surface to the A / T. Further, according to the A / T test apparatus 1, it is possible to confirm the influence on the A / T 7 due to the vibration caused by the fluctuation torque of the engine and the vibration transmitted from the road surface.
[0036]
In the above-described performance test, for example, when vibration occurs in the A / T7, an oil leak confirmation test for confirming whether or not an oil leak occurs in the A / T7, or no abnormal noise occurs in the A / T7. A performance test, such as an abnormal sound confirmation test, can be performed. Further, in the performance test, by operating the output motor 3 and the brake device 83, it is possible to confirm the influence on the A / T 7 when a load change (shock) acts on the A / T 7.
Therefore, according to the A / T test apparatus 1, various performance tests can be performed on the A / T 7 on the assumption that the A / T 7 is actually mounted on the vehicle.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram showing an A / T test apparatus with an A / T set in an embodiment.
FIG. 2 is an explanatory diagram showing an A / T test apparatus before A / T is set in the embodiment.
FIG. 3 is a diagram showing an A / T test apparatus in the embodiment, and is an explanatory diagram showing each unit located on the input shaft side of the A / T.
FIG. 4 is a diagram showing an A / T test apparatus in the embodiment, and is an explanatory diagram showing each unit located on the output shaft side of the A / T.
FIG. 5 is an explanatory diagram showing an A / T test apparatus with A / T set in a conventional example.
[Explanation of symbols]
1. . . A / T test equipment,
2. . . Input motor,
3. . . Output motor,
4. . . Input side support,
42. . . Input connection axis,
5. . . Output side support,
52. . . Output connection axis,
61. . . Input side constant velocity joint,
62. . . Output side constant velocity joint,
65. . . Input damper,
66. . . Output side damper,
7. . . A / T (automatic transmission),
71. . . housing,
72. . . Input shaft,
73. . . Output shaft,
81. . . Shaker,

Claims (3)

In an A / T test device that performs a performance test of an automatic transmission (hereinafter referred to as A / T),
The A / T test device includes an input motor for simulating the rotation of a vehicle driving engine,
An output motor for simulating the load applied to the A / T output shaft;
An input connection shaft connected to the input shaft of the A / T, and an input-side support portion for supporting the housing of the A / T;
An output-side support portion having an output connection shaft connected to the A / T output shaft;
The input motor and the input connection shaft, and the output motor and the output connection shaft are connected to each other by a constant velocity joint so as to be eccentric to each other, and are connected to the input side support portion and the output side support portion. An A / T test apparatus, characterized in that dampers for allowing these to swing are arranged between the fixed surfaces on which these are arranged. 2. The A / T test device according to claim 1, wherein the A / T test device has a vibration device for simulating a vibration transmitted from the road surface to the A / T, and the input side support portion or the output side support portion. A / T testing apparatus, wherein at least one of the A / T testing apparatuses is disposed on the vibration device via the damper. 3. The A / T according to claim 1, wherein the input motor is configured to generate a periodically fluctuating torque in order to simulate a vibration from the vehicle driving engine. Testing equipment.

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