DE29908113U1 - Device for testing material properties, in particular the strength, of plate-shaped components, in particular based on wood, by means of ultrasound - Google Patents

Description

LEINE & KING

PATENT ATTORNEYS

Dipl.-Ing. Sigurd Leine ■ Dipl.-Phys. Dr. Norbert König admitted to the European Patent Office European Patent Attorneys

Burckhardtstrasse 1 Telephone (0511) 623005

D-30163 Hanover Fax (0511) 6221

Our sign date

Electronic Wood Systems GmbH 378/001 30.04.1999

cw/eb

Device for testing material properties, in particular the strength, of plate-shaped components, in particular wood-based, using ultrasound

The invention relates to a device of the type mentioned in the preamble of claim 1 for testing material properties, in particular the strength, of plate-shaped components, in particular wood-based, by means of ultrasound.

Such devices are known. They have a test head for accommodating an ultrasonic transmitter, which generates ultrasonic signals for testing the component, and/or an ultrasonic receiver, which receives the ultrasonic signals after they have passed through the component or been reflected off it. To test the component, the component is exposed to ultrasonic waves by the ultrasonic transmitter, which are received by the receiver after they have passed through the component or been reflected off it. The material properties of the component can be assessed using the received ultrasonic signals.

The invention is based on the object of specifying a device of the type mentioned in the preamble of claim 1, which is easy to handle and works reliably.

This problem is solved by the teaching set out in claim 1.

The prestressing means according to the invention

a secure ultrasonic connection is ensured between the or each test head and the component to be tested, whereby the or each test head can be in contact with the component to be tested directly or via a coupling medium or a coupling device, for example in the form of a cushion. In this way, measurement errors are avoided which could arise if there is no perfect ultrasonic connection between the test head or the test heads and the component to be tested. The reliability of the measurement results is thus increased by using the pre-tensioning means according to the invention.

The device according to the invention is easy to handle. It can be used wherever testing of components using ultrasound is considered. The device according to the invention is particularly well suited to testing the material properties of panel-shaped wood-based components, in particular chipboard.

0 Furthermore, the device according to the invention is simple and inexpensive to manufacture.

A further development of the teaching according to the invention provides that the pre-tensioning means pre-tension the or each test head against the component essentially with a predetermined minimum force. In this way, each test head in the test position rests with a defined force on the component to be tested or on a coupling device connected to the component to be tested, so that the reliability of the measurement results is further increased.

The pre-tensioning means can be designed in any suitable manner. The pre-tensioning means expediently have at least one spring. Any suitable springs, for example

wise coil springs, can be used.

Another embodiment provides that the ultrasound transmitter and the ultrasound receiver are arranged in a common test head. In this embodiment, the structure of the device according to the invention is simplified. The ultrasound receiver receives the ultrasound signals after reflection from the component.

However, the ultrasound transmitter and the ultrasound receiver can also be arranged in a test head each, as another embodiment provides. In this embodiment, the component is clamped between the test heads in the test position. This simplifies the handling of the device according to the invention and ensures that the test heads are particularly securely attached to the component or a coupling device.

A base body on which the test heads are arranged can be designed in any suitable manner. A further development provides that at least

a test head is arranged on an arm of a pair of pliers. Another development of the teaching according to the invention provides that at least one test head is arranged on a movable holder which is arranged on a base body of the device and can be moved against the preload force of the preload means from a test position in which the test head is in ultrasonic connection with the component under the preload of the preload means, into a position in which the test head is lifted off the component.

In this embodiment, the preloading means preload the movable holder with the test head against the component to be tested.

The movement of the movable bracket can

the aforementioned embodiment can be carried out in any suitable manner. An advantageous embodiment provides that the holder can be moved between the test position and the position in which the test head is lifted off the component by means of a pivoting lever mounted pivotably on the base body. This embodiment is particularly simple and inexpensive to manufacture.

A further development of the aforementioned embodiment provides that a handle connected to the base body is arranged in the handling area of the end of the pivot lever facing away from the holder. In this embodiment, a user grasps the pivot lever to move the holder into the position in which the test head is lifted from the component and presses against the handle so that the component can be removed or a new component can be placed between the test heads. In this way, the operation of the device according to the invention is simplified. To clamp the component between the test heads, the user lets go of the pivot lever so that the test head arranged on the holder is moved into the test position under the pretension of the pretensioning means.

In principle, at least one of the test heads can be firmly connected to the base body, as one embodiment provides. However, the test head or at least one of the test heads is expediently exchangeable. In this way, the use of 0 different test heads is possible, for example for testing components made of different materials. In addition, in the event of a defect in a test head, it is only necessary to replace this test head in order to make the device functional again.

capable of making.

Any suitable ultrasonic waves can be used to test the components, the frequency of which can be selected within wide limits. However, the ultrasonic transmitter expediently generates longitudinal waves, the ultrasonic waves expediently having a frequency of less than approximately 1.5 MHz, preferably less than approximately 1 MHz.

Another development provides that the device has an evaluation device and/or an interface for connection to an evaluation device that evaluates the signals received from the ultrasound receiver to determine the strength properties of the component, in particular the transverse tensile strength and/or the bending strength and/or the bending elastic modulus and/or the thickness swelling and/or the density profile. The evaluation device determines material properties, in particular strength properties, of the components to be tested in a quick and simple manner on the basis of the received ultrasound signals. The evaluation device can be formed, for example, by a computer that is integrated into the device or can be connected to it.

If, in addition to the strength properties of the component, other parameters of the component are to be determined, the device can have any suitable measuring means for this purpose. For example, the device can have measuring means for measuring the thickness of the component and/or measuring means for measuring the temperature of the component, as provided for in embodiments.

In principle, the device according to the invention

The device can be arranged in a fixed location, for example in the form of a laboratory device. However, a particularly advantageous embodiment provides for the device to be handheld. In this way, the device is portable and mobile.

If the material properties of the component to be tested are to be determined along a measuring path relative to the component to be tested, the device can be guided along the measuring path by hand, for example. However, an advantageous further development provides a feed device by means of which at least the or each test head of the device can be moved along a measuring path relative to the component to be tested. In this embodiment, the test head or the entire device is moved along the measuring path, so that operation is further simplified.

The invention is explained in more detail below with reference to the accompanying drawing, in which an embodiment of a device according to the invention is shown in a highly schematic manner.

The drawing shows a hand-held device 2 which has a base body 4 with vertical guides 6, 8 on which a movable holder 10 for a first test head 12 is guided. The device 2 also has a second test head 14 which is arranged in a fixed position on the base body 4. One of the test heads 12, 14 contains an ultrasonic transmitter which, in the exemplary embodiment, generates longitudinal ultrasonic waves with a frequency of less than 1 MHz, while the other test head contains an ultrasonic receiver which, after passing through a part to be tested, transmits the ultrasonic waves sent by the ultrasonic transmitter.

receiving component 16.

The movable holder 10 with the first test head 12 is pre-tensioned in the direction of the component to be tested 16, in the drawing in the direction of an arrow 22, by pre-tensioning means, which in this embodiment are formed by two compression springs in the form of helical springs arranged between the movable holder 10 and a part of the base body 4. As a result, the component to be tested 16, which the test heads 12, 14 grip like pliers in the test position, is clamped between the test heads 12, 14 so that they lie firmly against the component 16 in the test position. In this way, an effective introduction of the ultrasonic waves into the component 16 is possible. If necessary, a coupling medium or a coupling device can be arranged between the test heads 12, 14 and the component 16.

The device 2 also has a pivoting lever 22 mounted on the base body, 0 the end of which faces the holder 10 rests against the latter, such that by pivoting the pivoting lever 22 in the direction of an arrow 24, the holder with the test head can be moved from the test position shown in Fig. 1, in which the test head 12 rests against the component 16 to be tested under the pretension of the springs 18, 20, to a position not shown in the drawing, in which the test head 12 is lifted off the component 16. In this position, the component 16 can be removed or exchanged for another component to be tested. A handle 26 connected to the base body 4 is arranged in the handling area of the pivoting lever 22. To move the holder 10 into the position in which the test head 12 is lifted off the component 16,

a user grasps the pivot lever 22 and the handle 26 with one hand and presses the pivot lever 22 towards the handle 26. The handle thus forms a counter-bearing for the actuation of the pivot lever 22.

The device 2 further comprises measuring means for measuring the temperature of the component 16, which in this embodiment is formed by a thermometer, the measuring tip 30 of which in the test position is

1.0 is applied to the component 16 to be tested. The device 2 also has measuring means for measuring the thickness of the component 16, which in this embodiment is formed by a displacement sensor 28 with a movable plunger 30. The test heads 12, 14, the thermometer 28 and the displacement sensor 30 are connected to a computer-aided evaluation device 42 via lines 34, 36, 38, 40.

The functioning of the device according to the invention 2 is as follows:

0 To test the component 16, the holder 10 with the first test head 12 is first moved upwards in the drawing using the swivel lever 22 against the preload force of the springs 18, 20, so that the component 16 can be introduced into the space between the test heads 12, 14. After releasing the swivel lever 22, the holder 10 with the first test head 12 moves against the component 16 under the preload force of the springs 18, 20 until the test heads 12, 14 rest on the component 16 and grip it like a pair of pliers. The thickness of the component 16 is determined using the displacement sensor 30 via the distance that the first test head 12 travels until it rests on the component 16. The temperature of the component 16 is determined using the thermometer 28. To test the

To determine the strength of the component 16, an ultrasonic transmitter (not shown in the drawing) housed in the first test head 12 generates ultrasonic waves which, after passing through the component 16, are received by an ultrasonic receiver (also not shown) housed in the second test head 16. The received signals are forwarded via line 34 to the evaluation device 42, which evaluates the signals to determine the transverse tensile strength and/or the bending strength and/or the bending elastic modulus and/or the thickness swelling and/or the density profile of the component 16 in a manner known to those skilled in the art. Any calculation of all measured values can be carried out in order to obtain correlating results about the properties of the component 16. If necessary, the evaluation device 42 can also contain fuzzy logic.

The device 2 according to the invention enables the material properties of the component 16 to be tested in a simple and quick manner. It is easy to handle and has a robust construction.

Claims (19)

LEINE & KING PATENT ATTORNEYS Djpl.-Ing. Sigurd Leine · Dipl.-Phys. Dr. Norbert König admitted to the European Patent Office European Patent Attorneys Burckhardtstrasse 1 Telephone (0511) 623005 D-30163 Hanover Fax (0511) 6221 Our sign date Electronic Wood Systems GmbH 378/001 26.04.1999 cw/eb Protection claims 1. Device for testing material properties, in particular the strength, of plate-shaped components, in particular wood-based, by means of ultrasound, with at least one test head for receiving an ultrasonic transmitter that generates ultrasonic signals for testing the component and/or an ultrasonic receiver that receives the ultrasonic signals after transmission through the component or reflection from it, marked by Preloading means which preload the test head (12, 14) in the direction of the component to be tested (16). 2. Device according to claim 1, characterized in characterized in that the prestressing means prestress the or each test head (12, 14) against the component (16) substantially with a predetermined minimum force. 3. Device according to claim 1 or 2, characterized in that the pretensioning means at least - 2 one
spring (18, 20). 4. Device according to one of the preceding claims, characterized in that the ultrasonic transmitter and the ultrasonic receiver are arranged in a common test head. 5. Device according to one of claims 1 to 3, characterized in that the ultrasonic transmitter and the ultrasonic receiver are each arranged in a test head (12, 14). 6. Device according to claim 5, characterized in that the test heads (12, 14) the component (16) in the test position like a pair of pliers. 7. Device according to claim 6, characterized in that at least one test head (12) is arranged on an arm of a pair of pliers. 8. Device according to one of the preceding claims, characterized in that at least one test head (12) is arranged on a movable holder (10) which is attached to a base body (4) of the device (2) and can be moved against the prestressing force of the prestressing means from a test position in which the test head (12) is in ultrasonic connection with the component (16) under the prestressing of the prestressing means 0 into a position in which the test head (12) is lifted off the component (16). 9. Device according to claim 8, characterized in characterized in that the holder (10) is movable between the test position and the position in which the test head (12) is lifted off the component (16) by means of a pivoting lever (22) pivotably mounted on the base body (4). 10. Device according to claim 9, characterized in that in the handling area of the end of the pivot lever facing away from the holder (10) (22) a handle (26) connected to the base body (4) is arranged. 11. Device according to one of claims 5 to 10, characterized in that at least one of the test heads (12, 14) is arranged stationary on the base body (4). 12. Device according to one of the preceding claims, characterized in that the test head or at least one of the test heads (12, 14) is exchangeable. 13. Device according to one of the preceding claims, characterized in that the ultrasonic transmitter generates longitudinal ultrasonic waves. 14. Device according to one of the preceding claims, characterized in that the ultrasonic waves have a frequency of less than about 1.5 MHz, preferably less than about 1 MHz. 15. Device according to one of the preceding Sayings, characterized in that the device (2) has an evaluation device (42) and/or an interface for connection to an evaluation device which evaluates the signals received from the ultrasound receiver to determine strength properties of the component (16), in particular the transverse tensile strength and/or the bending strength and/or the bending elastic modulus and/or the thickness swelling and/or the density profile. 16. Device according to one of the preceding claims, characterized in that the device (2) has measuring means for measuring the thickness of the component (16). 17. Device according to one of the preceding claims, characterized in that the device (2) has measuring means for measuring the temperature of the component (16). 18. Device according to one of the preceding claims, characterized in that the device (2) is hand-held. 19. Device according to one of the preceding claims, characterized by a feed device by means of which at least the or each test head (12, 14) of the device (2) can be moved along a measuring path relative to the component to be tested (16).