DE20012772U1 - Torque calibration device - Google Patents

Description

tUtility model application]

Renk AG PB 04434

[Title of the invention] Torque calibration device

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[Description]

The invention relates to a torque calibration device according to the preamble of claim 1.

[State of the art]

For torque calibration, for example in motor vehicle roller test benches, it is known to carry out this torque calibration using a device consisting of a lever mechanism that acts directly on the roller to be calibrated and which is loaded with mass elements, such as calibrated weights, in order to transmit a torque to the roller and thus to measuring instruments arranged on the roller. The entire device for torque calibration is located below the test level in the area of the

Rolls arranged. ·

The disadvantage of these calibration devices is that the operator has to transport the mass elements required for torque calibration to the lever mechanism located under the test plane and therefore has to go under the test plane. It is easy to understand that this process is very time-consuming and energy-consuming for the operator.

[Task of the invention]

The object of the invention is to provide a device for torque calibration with which a simple and accurate calibration is possible for the operator.

According to the invention, the object is achieved in a generic device by applying the features of the characterizing part of claim 1. Embodiments emerge from the subclaims and from the description in conjunction with the drawings.

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A significant advantage of the invention is that the introduction of the torque is shifted away from the lever arranged on the torque measuring system via the lever mechanism located on the torque calibration device to an easily accessible level.

A significant advantage of the torque calibration device is that it can be easily removed from the device to be calibrated, for example a torque measuring system, and has a compact design. Furthermore, the device can be moved, for example, via a conveyor or arranged roller elements.

A further advantage of the torque calibration device is that the mass elements required for calibration are integrated in a magazine element and the torque generated by the mass elements via a lever mechanism is transmitted to the torque measuring system via the same lever mechanism.

The torque calibration device therefore does not have to be located in the immediate vicinity of a torque measuring system.

When using the device, for example, on torque measuring systems that are difficult to access due to their design, such as roller test benches, it can be arranged above a test level.
It is particularly worth mentioning that the mass elements are lifted to the lever mechanism that transmits the torque by means of a lifting device arranged on the device. This means that the operator does not have to perform any physically strenuous activities when adjusting the torque calibration device, even though the mass elements are designed as weights.

A significant advantage is the simple adjustment of the force causing the torque by means of the mass elements. The mass elements are stacked in the magazine element of the device, whereby the mass elements not required for calibration can be separated from the required mass elements by means of a holding element, whereby

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the mass elements that are not required are locked to the magazine element by means of the holding element and therefore have no influence on the calibration process.

A significant variant of the device is provided by equipping the lever mechanism of the device with a lever transmission, so that mass elements can be saved or the mass of the individual mass elements can be reduced by the factor of the transmission. This has the advantage that the operator can handle the device with even less physical effort.

[Examples]

The invention will be explained in more detail below using an exemplary embodiment. It shows schematically:

Fig. 1 a torque calibration device for generating a torque on a roller element of a roller test stand to be calibrated and

Fig. 2 is a side view according to Fig. 1, partially sectioned.
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Fig. 1 shows a torque calibration device (1) for generating a torque on a torque measuring system, for example on a roller element (2) of a motor vehicle and/or tire roller test stand to be calibrated. The device (1) consists of a guide element (4) which can be arranged on a test plane (3) and on which a base plate (5) is mounted. A magazine element (6), a support means (7) and a lifting device (8) are arranged on the base plate (5). The lifting device (8) is, for example, a

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hydraulically or pneumatically operated working cylinder or an electromechanically driven lifting device. Mass elements (9) are movably arranged in the magazine element (6) and can be positioned in a fixed position in the magazine element (6) by means of a holding element (10). The mass elements (9) are provided with bores (11) for receiving the holding element (10) (see Fig. 2). A lever element (12) is movably mounted on the support means (7), on which a rod element (13) and a rod element (14) are arranged. The lever element (12) can be locked in a horizontal position by means of a mechanism not described in more detail. A support element (15) is arranged on the rod element (14). The rod element (14) is guided through bores (16) in the mass elements (9).

The rod element (13) serves as a means of transmitting the torque exerted by the mass elements (9) on the lever element (12) to a lever (17) arranged on the roller element (1) to be calibrated. The rod element (13) is attached to the lever (17) with a detachable and loss-free connection, for example a connection of cutting edges (18). The base plate (5) is slidably mounted on the guide element (4) by means of roller elements (19) and can be locked on the guide element (4) by mechanisms not described in detail.

The guide element (4) is movably mounted on the test plane (3). It can be moved using conveyor means (20), for example using a chain drive embedded in the test plane (3). It is also possible to make the guide element (4) movable, for example using roller elements (not shown in detail).

The device is positioned on the roll (2) to be calibrated by means of the conveyor (20) arranged on the guide element (4). The rod element (13) is connected to the lever (17) of the roll (2) and the lever element (12) of the device (2). The masses are

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elements (9) are raised up to a stop (21) arranged on the magazine element (5). The holding element (10) can now be pulled out.

Depending on the torque required for calibration, the support element (15) is loaded with a certain number of mass elements (9). The mass elements (9) that are not required are locked to the magazine element (6) using the holding element (10) and therefore have no influence on the calibration process.

The lifting device (8) is lowered again, so that only the mass elements (9) required for calibration rest on the support element (15). To start the calibration process, the mechanism that locks the lever element (12) in its horizontal position is finally released and the force of the mass elements (9) located on the support element (15) exerts a defined torque on the roller (2) and thus on the measuring instruments and/or measuring equipment arranged on it via the lever mechanism (12, 13, 14, 16).

A variant of the device according to Fig. 1 results in that the lever element (12) is arranged on the support means (7) in such a way that a transmission is achieved by means of which fewer and/or smaller mass elements (9) are required to generate a certain torque than in comparison to the device according to Fig. 1.

For example, a lever element (12) could be arranged with a lever ratio of 1:5, so that only 1/5 of the mass elements (9) required in comparison to Figure 1 is required or the mass of the individual mass elements (9) corresponds only to 1/5 of the mass of the mass elements (9) of Figure 1.

The torque calibration device should not be limited to use with vehicle or tire roller test benches. The torque calibration device can be used

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any technical device where a specific torque is to be calibrated can be used.

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[List of reference symbols]

1 Torque calibration device 5 2 Torque measuring system 3 Test level 4 Guide element 5 Base plate 6 Magazine element 10 7 Supporting equipment 8th Lifting device 9 Mass element 10 Holding element 11 drilling 15 12 Lever element 13 Rod element 14 Rod element 15 Support element 16 drilling 20 17 lever 18 Screw connection 19 Roller element 20 Funding 21 attack

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Claims (8)

1. Torque calibration device ( 1 ) consisting of mass elements ( 9 ) arranged in a magazine element ( 6 ), which introduce a torque via a lever element ( 12 ) due to their mass by means of a lever mechanism ( 12 , 13 , 14 , 17 ) onto a torque measuring system ( 2 ). 2. Device according to claim 1, characterized in that the lever mechanism ( 12 , 13 , 14 , 17 ) is equipped with a transmission. 3. Device according to claim 2, characterized in that the lever element ( 12 ) is equipped with a transmission. 4. Device according to one of claims 1 or 3, characterized in that the mass elements ( 9 ) can be positioned on the lever mechanism ( 12 , 13 , 14 , 17 ) by means of a lifting device ( 8 ). 5. Device according to claim 4, characterized in that mass elements ( 9 ) required for calibration can be switched to a support element ( 15 ) by removing a holding element ( 10 ) from the magazine element ( 6 ). 6. Device according to one of claims 1 to 5, characterized in that the torque calibration device can be arranged on a movable guide element ( 4 ) and on a base plate ( 5 ) displaceably mounted on the guide element ( 4 ). 7. Device according to one of claims 1 to 5, characterized in that the guide element ( 4 ) can be moved by means of a conveying means ( 20 ). 8. Device according to claim 6, characterized in that the conveying means ( 20 ) is a chain drive, for example a conveyor chain.