WO2019091823A1

WO2019091823A1 - Abrasive disk, hand-held power tool and control method

Info

Publication number: WO2019091823A1
Application number: PCT/EP2018/079648
Authority: WO
Inventors: Franz Mandl
Original assignee: Hilti Aktiengesellschaft
Priority date: 2017-11-10
Filing date: 2018-10-30
Publication date: 2019-05-16
Also published as: EP3706955A1; EP3482876A1; US20210023675A1; CN111132801A; CN111132801B

Abstract

The invention relates to an abrasive disk (2) comprising at least one layer (17, 16, 18) in which abrasive centre punches are embedded. A sensor (22) for detecting an original periphery (20) of the abrasive disk (2), which has been modified by wear, is embedded in one layer (25). The sensor (225) has at least one closed conductor loop (23) which is arranged within a radial distance (27) from the original periphery (20) such that, when the wear of the original periphery (20) exceeds the radial distance (27), the conductor loop (23) is interrupted. A transponder (15) emits a radio signal that indicates whether the conductor loop (23) is closed or interrupted.

Description

Abrasive disc, hand tool and control method

FIELD OF THE INVENTION

The present invention relates to a disc, a portable power tool for abrasive discs and a control method.

Abrasive discs rotate at high speed. When using the disc, abrasion of the disc and the machined material fly away from the disc at high speed. Furthermore, the disc is subject to high loads due to centrifugal force. For safety reasons, therefore, the regulatory authorities set an upper limit for the speed of rotation. Abrasive discs are subject to wear. The wear leads to a reduced extent and thus reduced rotational speed. The reduced rotational speed adversely affects the machining performance of the discs.

DISCLOSURE OF THE INVENTION

An abrasive disc according to the invention has one or more layers in which abrasive grains are embedded. In one layer, sensor for detecting a wear-modified original circumference of the abrasive disc is embedded. The sensor has at least one closed conductor loop, which is arranged at a radial distance from the original circumference such that when the original circumference is worn by more than the radial distance, the conductor loop is interrupted. A transponder gives a radio signal indicative of whether the conductor loop is closed or interrupted. The radio signals indicate the radial wear of the disc. A hand tool can adjust the speed accordingly.

A hand tool for the abrasive disc has a holder for the abrasive disc, an electric motor for rotating the abrasive disc and a speed control for the electric motor. A communication device is set up by the Transponder of the abrasive disc output radio signal. A device controller sets the speed for the speed control based on the received radio signal. BRIEF DESCRIPTION OF THE FIGURES

The following description explains the invention with reference to exemplary embodiments and figures. In the figures: FIG. 1 shows an electrical cut-off grinder. FIG

Fig. 2 shows an abrasive disc in cross section

Fig. 3, the abrasive disc in a plan view

Fig. 4 shows a section of an abrasive disc

Fig. 5 shows a section of an abrasive disc

Identical or functionally identical elements are indicated by the same reference numerals in the figures, unless stated otherwise.

EMBODIMENTS OF THE INVENTION

The hand tool 1 has a tool holder 3 for an abrasive disc 2. The tool holder 3 is coupled to an electric motor 4 which rotatably drives the tool holder 3 about its axis. A speed control 5 controls the electric motor 4. The speed control 5 limits the speed to a maximum speed in order to prevent damage to the abrasive wheel 2 and possible damage to the user. A protective cover 6 surrounds more than half of the tool holder 3 in an annular fashion in order to protect the user from flying sparks and separating material. The hand tool 1 has a handle 7 with which the user can hold and guide the hand tool 1 in operation. At or near the handle 7, a button 8 for the commissioning of the electric motor 4 is arranged. The hand tool 1 can be network-based or powered by batteries 9. The hand tool 1 has a device control 10. The device control 10 sets, among other things, the target speed for the speed control 5 fixed. The device controller 10 can access a memory 11 in which a target speed is stored. The Device controller 10 may also access a communication device 12 to communicate with an abrasive disc 2. The communication device 12 has a transmitter 13 for emitting radio-based signals and a receiver 14 for receiving a radio-based response of the abrasive disc 2. A transmission power of the transmitter 13 is preferably sufficient to a transponder, such as an RFID chip, without its own power source on the transmission power to provide energy.

The device controller 10 directs when pressing the button 8 a request to the disc 2 to identify them. The disc 2, if equipped with a transponder 15, reports an identification number or type number. The device controller 10 checks if the type number differs from the last used slice 2. If this is the case, the device control 10 queries an allowable maximum speed for the disc 2. The apparatus controller 10 stores the allowable maximum speed in the memory 11. Preferably, the disk 2 transmits a list of different maximum speeds to be used depending on a degree of wear of the disk 2. The degree of wear is coded in radio signals which are transmitted in the list. The device controller 10 stores the list in the memory 11. The device controller 10 sets the speed of the speed control 5 to the allowable maximum speed, which corresponds to the current degree of wear. The device controller interrogates at intervals the degree of wear of the disc 2 via the communication device 12. The radio signal received in response from the communication device 12 is compared with the stored list. The radio signal associated maximum allowable speed is transmitted to the speed control 5. Fig. 2 shows schematically an embodiment of an abrasive disc 2 in cross section. The abrasive disc 2 shown is a multi-layer blade with different abrasive grains. The abrasive disc 2 has a middle layer 16 with first grains. The middle layer 16 can be produced for example by a galvanically deposited matrix in which the grains are distributed. The two outer layers 17, 18 can also be made with an electrodeposited matrix and scattered embedded grains. The grains of the middle layer 16 may be larger than the grains of the outer layers 17, 18. The exemplary grains have a diameter of 4 μηη to 10 μηη or 10 μηη to 20 μηη. The production of the layers 18 is purely exemplary. Another exemplary method is based on fabrics that are potted with the grains of blended resins. The resins are then cured. The number of different layers is also purely exemplary. Other discs have one, two or more different abrasive layers. Typically, the discs 2 are provided with a cover layer 19, on which disc type, manufacturer, etc. are indicated.

The discs are made with different diameters. Exemplary diameters are 8.9 cm and 1 1, 2 cm. Fig. 3 illustrates exemplary wear. The reconditioned disc 2 has the original circumference 20. The discs 2 wear off during use, thereby reducing the diameter and circumference. Dashed examples of a circumference 21 of a worn disc 2 are shown. In the following, the original diameter, original radius or original circumference 20 designates the respective property of a new, unused abrasive disc 2.

In the abrasive disc 2, a sensor 22 is embedded, which detects wear and the degree of wear of the disc 2. The sensor 22 is based on one or more closed conductor loops 23, 24. The conductor loops 23, 24 run parallel to the abrasive layers 16. For example, the conductor loop 23 may be printed on a sheet of non-conductive plastic. The film is stacked as a further layer 25 with the other layers 16. The film can be arranged on the abrasive layers 16 or between the abrasive layers 18 as shown. The conductor loops 23, 24 have a low mechanical strength. The conductor loops 23, 24 preferably have a height of less than 100 μηη. The conductor loops 23, 24 are preferably made of copper or graphite.

The closed conductor loop 23 has a (detection) portion 26 which is farthest from the periphery 20 and from a center of the disk 2, respectively. The detection section 26 has a radial distance 27. The exemplary detection section 26 lies within the original circumference 20 and outside a worn circumference 21. The radius of the worn circumference 20 corresponds to the original radius decreased by the distance 27. The detection section 26 will wear when the Disk 2 by the distance 27, ie exposed to the worn circumference 21 and destroyed. The previously closed conductor loop 23 is now interrupted.

On the disc 2, a sensor 22 is preferably arranged, for example, in the position 25 with the conductor loops. The sensor 22 may be realized, for example, as an RFID chip. The sensor 22 checks the closed or interrupted state of the conductor loop 23. The sensor 22 determines the electrical properties of the conductor loop 24, such as resistivity, inductance and electromagnetic resonance frequency. The sensor 22 For example, based on an ohmmeter for determining the electrical resistance of the conductor loop 23. If the resistance value exceeds a threshold value, for example 1 megohm, the conductor loop 24 is interrupted, otherwise the conductor loop 23 is considered to be closed. The conductor loop 23 is galvanically connected to the sensor 22. The ohmmeter applies a voltage to the conductor loop 23 and measures the amplitude of the current flowing in the conductor loop 23. Another embodiment of the sensor 22 determines the inductance of the conductor loop 23. A further embodiment of the sensor 22 determines whether the resonant frequency of the conductor loop 23 changes. The conductor loop 23 may be part of an electrical resonant circuit or inductively coupled to a resonant circuit of the sensor 22. While the conductor loop 23 or the resonant circuit can be excited at a predetermined resonant frequency when the conductor loop 23 is closed, this is not possible when the conductor loop is interrupted or when at a different resonant frequency. The sensor 22 excites the resonant circuit at the predetermined resonant frequency. If the power consumption exceeds a threshold value due to the resonant excitation, the conductor loop 23 is considered as closed otherwise as interrupted. The described embodiments for determining the electrical properties of the conductor loop 23 are exemplary. The sensor 22 may also be passive. An external transmission source excites the resonant circuit 28. The sensor 22 includes a transponder 15. The transponder 15 may consist of a passive antenna. The transponder 15 transmits the state of the conductor loop, ie whether the conductor loop is interrupted or whether the conductor loop is closed.

In one embodiment, the sensor 22 includes a memory 29, in which characteristics of the abrasive disc 2 are stored. For example, in the memory 29, a maximum permissible speed for the disc 2 is stored with the conductor loop 23 closed and a maximum permissible speed for the disc 2 when the conductor loop 23 is interrupted. The sensor 22 determines the currently permissible speed based on the determined state of the conductor loop 23. The permissible speed is output via the transponder 15. In one embodiment, the transponder 15 may have both values, i. for the closed and the broken conductor loop 23, at once to the communication device 12 of the power tool 1 transmit. At the same time, the transponder 15 transmits the radio signals or their coding for the two states. An evaluation can thus be transmitted to the device controller 10.

In addition to the first conductor loop 23 described, the sensor 22 may have a second conductor loop 24 or a plurality of conductor loops. The second conductor loop 24 has a greater distance 30 to the original circumference 20. Accordingly, the second conductor loop 24 is severed only at a greater degree of wear 31. The second conductor loop 24 has, like the first conductor loop 23, a detection section 32. The detection section 32 is destroyed when the abrasive disc 2 is worn away by more than the distance 30. The sensor 22 detects whether the second conductor loop 24 is closed or interrupted. The two conductor loops 23, 24 can be galvanically isolated as shown. The sensor 22 can scan the conductor loops 23, 24 in succession. With the second conductor loop 24, three states of wear can be distinguished: low, medium, high. For each of the wear conditions, a separate maximum speed can be defined, and stored, for example, in the memory 29. The transponder 15 transmits a radio signal in which the state of both conductor loops 23, 24 is coded. The number of conductor loops 23, 24 may be greater than two, eg up to ten conductor loops. The sensor 22 and the memory 29 need only be scaled accordingly. Fig. 4 and Fig. 5 show other embodiments of the conductor loops, in which the conductor loops 33, 34 are galvanically connected. A first conductor loop 33 has the smallest distance 27 to the original circumference 20. A second conductor loop 24 has a greater distance 30 to the original circumference 20. Their respective detection sections 35, 36 are radially offset from one another, as in the first embodiment.

For example, the sensor 22 may determine the change in resistance of the connected conductor loops. The conductor loops 33, 34 form an electrical parallel connection. With each broken conductor loop 33, the resistance value of the parallel circuit increases. The conductor loops 33, 34 preferably each have a clearly measurable resistance 37. The resistor 37 may be made, for example, by using graphite instead of a metal for the conductor loops 33, 34.

The sensor 22 may determine the inductance or resonant frequency of the parallel-connected conductor loops 33, 34. The inductance of the parallel circuit decreases with each severed conductor loop 33. The resonant frequency increases with each separated conductor loop 33. The parallel-connected conductor loops 33, 34 may be part of a resonant circuit 28 of the sensor 22 or inductively excited via a resonant circuit 28 of the sensor 22.

Claims

Abrasive disc (2) with

one or more layers (17, 16, 18) in which abrasive grains are embedded and a sensor (22) embedded in a ply (25) for detecting an abrasion - modified original circumference (20) of the abrasive disc (2) Sensor (22) has at least one closed conductor loop (23) which is arranged at a radial distance (27) to the original circumference (20) such that when the original circumference (20) is worn by more than the radial distance (27 ) the conductor loop (23) is interrupted and

a transponder (15) emitting a radio signal indicative of whether the conductor loop (23) is closed or interrupted.

Abrasive disk (2) according to claim 1, characterized in that the sensor (22) has at least one further closed conductor loop (24) which is at a greater distance (30) from the one of the conductor loop (23) radial distance (27) the original circumference (20) are arranged, and wherein the transponder (15), a radio signal indicative of which of the conductor loops (23, 24) are interrupted is issued.

Abrasive disk (2) according to claim 2 or 5, characterized in that at least two of the conductor loops (23, 24) have a different radial extent.

Abrasive disc (2) according to claim 2 or 5, characterized in that at least two of the conductor loops (23, 24) have a different length.

Abrasive disk (2) according to one of the preceding claims, characterized in that at least two of the conductor loops (23, 24) have a different electromagnetic resonance frequency.

Abrasive disc (2) according to one of the preceding claims, characterized in that the conductor loops (24) and the transponder (15) are printed on a foil.

Abrasive disc (2) according to one of the preceding claims, characterized by a memory (29) integrated in the sensor (22), in which a measure of a maximum permissible rotational speed of the abrasive disc (2) in dependence on each severed conductor loop (23, 24) is deposited, wherein the transponder (15) is the measure of the maximum speed in the radio signal issuing.

Abrasive disk (2) according to one of the preceding claims, characterized in that the sensor (22) and the transponder (15) are integrated in an RFID.

Hand tool for the abrasive disc (2) according to one of the preceding claims, with

a holder (3) for the abrasive disc (2),

an electric motor (4) for rotating the abrasive disc (2),

a speed control (5) for the electric motor (4),

a communication device (12) receiving the radio signal output from the transponder (15) of the abrasive disc (2), and

a device controller (10) that sets the speed for the speed control (5) based on the received radio signal.

10. Hand tool according to claim 9, characterized in that the device controller (10) determines a nominal speed when the communication device (12) receives no radio signal.

Powered hand tool (1) according to claim 9 or 10, characterized by a memory (1 1) in which a list of speeds for the electric motor (4) are stored to radio signals from abrasive discs.

Hand tool (1) according to claim 1 1, characterized in that the device control (10) is a list of maximum speeds and associated radio signals from a memory (29) of the abrasive disc (2) is read out and this list in the memory (1 1) the hand tool (1) stores.

Control method for a hand tool according to claim 9, comprising the steps:

Sending a request about the wear state of a disc (2),

Adjusting a speed of the hand tool (1) based on the received radio signal.

14. Control method for a hand tool (1) according to claim 13, characterized by the steps:

Sending a request for maximum speeds and associated radio signals indicative of the degree of wear,

Storing the maximum speeds and associated radio signals in one

Memory (1 1) of the portable power tool (1),

wherein for adapting a speed from the memory (1 1) of the power tool (1) the maximum speed associated with the received radio signal is read out.