EP3391993A1 - Abrasive cut-off machine - Google Patents

Abstract

A cut-off grinder (200) having a gear neck (210) for connecting a dust hood (100, 100 ') equipped with a flange (90), wherein the cut-off grinder (200) has a sensor unit (20) by means of which it is possible to detect which type of dust hood (100, 100 ') is connected to the cut-off grinder (200), wherein the cut-off grinder (200) further comprises a direction of rotation control electronics (230), which is signal-connected to the sensor unit (20), such that the direction of rotation (GGD, GLD) of a cutting disc (220) of the cutting-off grinder (200) is predefined as a function of the dust-hood type detected by the sensor unit (20).

Description

The present invention relates to a power cutter having a gear neck for connecting a dust cap equipped with a flange.

Such cut-off grinders are basically known from the prior art. Dust hoods are typically equipped with a dust cover to prevent the spread of dust during the cutting process, by means of which a background removal can be extracted from the hood body. Furthermore dust hoods are known, which have a flushing port, through which rinse water can be guided in the dust hood for the purpose of dust removal. Both types of dust hoods protect the health of a user of the cutting machine.

It is an object of the present invention to provide a cut-off grinder, which is set up in particular with regard to the operation with a dust hood to avoid operating errors.

The object is achieved in that the cut-off machine has a sensor unit, by means of which it is possible to detect which type of dust hood is connected to the cut-off machine, wherein the cut-off machine further has a direction of rotation control electronics, which is signal-connected to the sensor unit, such that the direction of rotation of a separating disk of the cutting grinder is specified as a function of the dust hood type detected by the sensor unit.

The invention includes the recognition that prior art cutoff grinders can be operated in various modes of use, which also depend, in particular, on the type of cutting and dust removal. Thus, for example, in the so-called dry cutting without dust extraction a cutting disc of the cutting grinder is driven in the same direction of rotation. The same is the case with so-called wet cutting, in which rinse water is introduced into the dust hood via a flushing connection. When dry cutting with dust extraction, however, an opposite direction of rotation of the cutting wheel of the cutting grinder is preferred.

By means of the sensor unit provided according to the invention and the direction of rotation control electronics connected to this sensor unit, a direction of rotation of a cutting disc can now be preselected automatically, namely as a function of the dust hood type detected by the sensor unit. As a result, operating errors in the direction of rotation can be excluded, which significantly increases the safety and health of a user of the cutting machine.

In a particularly preferred embodiment can be detected by means of the sensor unit, if the dust hood is connected to the cutting grinder. Preferably, the rotary control electronics is further configured to prevent rotation of the cutting disc when no dust hood is connected to the cutting grinder.

It has proven to be advantageous if the sensor unit is arranged on a surface of the cut-off wheel, preferably near the gear neck. The sensor unit can be arranged on a gripping end face of the cut-off grinder. In principle, it should be noted that, depending on the specific space conditions on the cut-off machine and, depending on the technical feasibility, the position of the sensor unit can be adapted accordingly to the cut-off machine.

It has proven to be advantageous if the sensor unit has a hood contact, by means of which it can be detected whether the dust hood is connected to the cut-off machine. Also preferably, the sensor unit may have a hood-type contact, by means of which a preferably mechanical coding of the dust hood connected to the cut-off machine can be read out.

The hood contact and / or the hood type contact may be provided in the form of a switch, a button, a magnetic contact or a light barrier. A combination of these components is also conceivable. In the following, some preferred embodiments will be described in more detail.

The hood type contact may be provided, for example, in the form of an on / off / on slide switch disposed on a surface of the cutting grinder. The slide switch may for example be arranged and arranged such that an inclined plane formed on the dust hood actuates the slide switch. In this respect, an inclined plane of a hood can represent a mechanical coding which is read out by the hood type contact, in the present example thus the slide switch. Accordingly, different oblique planes are to be provided on different hood types.

Alternatively or in addition to the inclined plane described, mechanical codings in the form of a projection, recess or the like can be provided on the dust hood. The slide switch can be arranged, for example, that it is pushed to the right when connecting a dust hood with suction, which has a first mechanical coding. It may also be provided that the slide switch is pushed to the left when attaching a dust hood with flushing connection, which has a second, different from the first coding coding. Alternatively or additionally, it may be provided that, if no dust hood is arranged on the cut-off wheel, the slide switch remains in the middle position and, caused by the direction of rotation control electronics, then a rotation of the cutting disc is completely prevented.

The invention is also solved by a system comprising a previously described cut-off grinder and two dust hoods of different types, the type each being defined by a preferably mechanical coding which can be read out by the sensor unit of the cut-off grinder.

The invention is likewise achieved by a dust hood which has on its surface a preferably mechanical coding which can be read out by a sensor unit of a cut-off grinder.

In addition, preferred embodiments of the abrasive cutter are described. Preferably, it is provided in all described embodiments that when the sensor unit detects a dust hood with flushing connection, a synchronous direction of rotation of the cutting disc is predetermined and / or if the sensor unit detects a dust hood with suction, the blade is given an opposite direction of rotation.

The hood contact and the hood type contact may be functionally integrated, for example, by the provision of an on / off / on toggle switch, which is preferably operated by a survey on a dust hood. For example, it may be provided that a dust hood with flushing connection actuates the toggle switch in a first on position, whereby an electrical signal is fed to the direction of rotation control electronics, which leads to a synchronous direction of rotation of the cutting disk when the cut-off grinder is activated.

In the second on position of the toggle switch can be brought by attaching a dust hood with exhaust. Accordingly, an opposite direction of rotation of the blade is effected. When toggle switch in off position (middle position), a rotation of the cutting disc is preferably completely prevented because no dust hood is connected to the cut-off. From this example, it is particularly clear that one and the same switching element, in the present case the toggle switch, can form both the hood contact and the hood type contact.

Instead of the on / off / on-toggle switch just described, an on / off toggle switch may also be provided. This is preferably actuated by an inclined plane on the hood. In this embodiment, the toggle switch forms only a hood type contact, can be specified via the opposite direction of rotation or the same direction of rotation.

In a further preferred embodiment, the sensor unit may comprise two buttons, which together realize the hood contact and the hood type contact. The buttons are preferably arranged such that a first mechanical coding on the dust hood with rinsing connection actuates the first button and does not actuate the second button. Whereas a dust hood with extraction nozzle has a second coding, which differs from the first coding, which actuates the second key and leaves the first key unoperated. If neither a dust hood with a suction nozzle nor a suction hood with flushing connection is connected to the cut-off machine, then both buttons remain preferably unactuated. In this case, a rotation of the cutting disc is prevented by the direction of rotation control electronics as soon as the cut-off grinder is activated.

In a further preferred refinement, the sensor unit of the cut-off grinder has only one hood-type contact, which is preferably provided in the form of a push-button. The direction of rotation control electronics is set to specify a direction of rotation in the same direction when the button is pressed and to specify an opposite direction of rotation when the button is not pressed.

In a further preferred embodiment, the hood contact and / or the hood type contact can be provided by one or more light barriers. It is preferably provided that a mechanical coding of the dust hood with rinsing connection causes an interruption of the first light barrier and a mechanical coding on the dust hood with suction nozzle causes an interruption of the second light barrier. In this respect realize the first and the second photoelectric switch a hood type contact. If neither of the two light barriers is interrupted, this means that no or a manufacturer-external dust hood is connected to the cut-off machine. The first and second light barrier thus also realize a hood contact, which causes that if neither of the two light barriers is interrupted, a rotation of the cutting disc is prevented.

In a further embodiment, exactly one light barrier can be provided, which acts only as a hood type contact. It can be provided that a dust hood with rinsing connection interrupts this light barrier, whereas a dust hood with suction connection does not interrupt the light barrier.

In a further preferred embodiment, the hood contact and / or the hood type contact can be realized by one or more magnetic switches, which are provided by magnets on the hood. In this respect, the magnetic switches define the sensor unit and the magnet or magnets on the hood mechanical coding. It is preferably provided that a dust hood with a suction nozzle has a first magnetic coding which actuates a first magnetic switch, for example a reed contact. It can further be provided that a dust hood with flushing connection has a second coding which is different from the first magnetic coding and which is arranged such that the second magnetic switch is activated on the cut-off grinder. If no dust hood is provided on the cut-off machine, the direction-of-rotation control electronics suppress the rotation of the cut-off wheel.

The switching functions of the individual contacts explained in the context of the exemplary embodiments can of course also be logically inverted.

According to a self-protectable aspect, a power cutter is provided with a gear neck for connecting a dust hood equipped with a flange. The cut-off machine has a sensor unit, by means of which it can be detected whether a dust hood is connected to the cut-off machine, wherein the cut-off machine further has a direction of rotation control electronics, which is signal-connected to the sensor unit, such that rotation of the cut-off wheel is prevented, if no dust hood connected to the cut-off machine.

• Detektieren, mittels einer von dem Trennschleifer umfassten Sensoreinheit, welcher Typ von Staubhaube am Trennschleifer angeschlossen ist,
• Steuern einer Drehrichtung der Trennscheibe des Trennschleifers in Abhängigkeit des von der Sensoreinheit detektierten Zustands.

The invention is also achieved by a method of operating a cutting machine having a gear neck for connecting a dust hood equipped with a flange, the method comprising the following steps:

• Detecting, by means of a sensor unit comprised by the cut-off machine, which type of dust hood is connected to the cut-off machine,
• Controlling a direction of rotation of the cutting wheel of the cutting grinder as a function of the state detected by the sensor unit.

Preferably, the step of detecting includes reading out a mechanical coding of the dust hood connected to the cut-off machine.

Preferably, the power cutter is a hand tool. Most preferably, the abrasive grinder is battery powered, i. especially without mains cable.

Further advantages will become apparent from the following description of the figures. In the figures, various embodiments of the present invention are shown. The figures, the description and the claims contain numerous features in combination. The person skilled in the art will expediently also consider the features individually and combine them into meaningful further combinations.

In the figures, identical and similar components are numbered with the same reference numerals.

Fig. 1

ein bevorzugtes Ausführungsbeispiel eines erfindungsgemäßen Trennschleifers;

Fig. 2

ein bevorzugtes Ausführungsbeispiel eines Systems mit einem Trennschleifer und zwei Staubhauben unterschiedlichen Typs;

Fig. 3

ein weiteres Ausführungsbeispiel eines erfindungsgemäßen Trennschleifers;

Fig. 4

ein anderes bevorzugtes Ausführungsbeispiel eines erfindungsgemäßen Trennschleifers; und

Fig. 5

ein erfindungsgemäßes Verfahren zum Betreiben eines Trennschleifers.

Show it:

Fig. 1

a preferred embodiment of a cutting grinder according to the invention;

Fig. 2

a preferred embodiment of a system with a power cutter and two dust hoods of different types;

Fig. 3

a further embodiment of a cutting grinder according to the invention;

Fig. 4

another preferred embodiment of a cutting grinder according to the invention; and

Fig. 5

an inventive method for operating a cutting grinder.

EXAMPLES

A preferred embodiment of a cutter 200 according to the invention is shown in FIG Fig. 1 shown. Connected to the cut-off grinder 200 is a dust hood 100 for at least partially covering both sides of a circular cutting disk 220. The dust hood 100 has a suction connection 40, via which a background removal from the hood body 10 can be sucked off. The suction nozzle 40 has a flap 45. A suction hose 40 to be introduced into the suction hose is in Fig. 1 not shown.

The cut-off machine 200 has a sensor unit 20 which is arranged on a surface OF of the cut-off grinder 200. The cut-off machine 200 also has a direction-of-rotation control electronics 230, which is signal-connected to the sensor unit 20 via the signal line 80. The direction of rotation control electronics 230 is set up to predetermine the direction of rotation of the cutting disk 220 as a function of the sensor signal SL coming from the sensor unit 20.

The sensor unit 20 has a hood-type contact 27 in the form of a pushbutton, by means of which a mechanical coding 110 of the dust hood 100 can be read out. Im in Fig. 1 illustrated embodiment, the mechanical coding 110 is realized by an inclined plane, which is formed on the hood body 10 of the dust hood 100.

The direction of rotation control electronics 230 is set up to cause an opposite direction of rotation GGD of the cutting disk when the button is pressed (hood type contact 27). This corresponds to a dry cutting operation with dust extraction.

If, however, instead of the dust hood 100 with suction nozzle 40, for example, a dust hood with flushing connection (see. Fig. 2 : Dust hood 100 ') connected to the cutting machine, so would be given by the direction of rotation control electronics 230 a co-rotating direction GLD, which would mean a wet cutting operation without dust extraction.

Fig. 2 shows a system 600 with a cut-off machine 200 and two dust hoods 100, 100 'of different types. Top in Fig. 2 can be seen a dust cover 100 with suction 40. In the suction nozzle 40, a suction hose 400 can be inserted, via which a background removal UG can be sucked out of the dust cover 100. On the hood body 10 of the dust hood 100, a first mechanical coding 110 is formed in the form of a simple elevation.

Bottom right in Fig. 2 another type of dust hood is shown, namely a dust hood 100 'with flushing connection 50. A flushing hose 500 can be connected to the flushing connection 50. The dust hood 100 'has a second mechanical coding 110' in the form of a double elevation.

On the left side of the Fig. 2 illustrated is the cut-off machine 200 with a gear neck 210 to which both the dust cover 100 with suction 40 and the dust hood 110 with flushing port 50, respectively via its flange 90, can be connected.

In the present exemplary embodiment, the cut-off machine has a sensor unit 20 which has both a hood contact 25 and a hood-type contact 27. By way of example, the hood contact 25 and the hood contact 27 should be functionally integrated in the form of an on / off / on toggle switch.

The power cutter 200 has a direction of rotation control electronics 230 which is connected via a signal line 80 to the sensor unit 20. The direction of rotation control electronics 230 is set up, the direction of rotation of the cutting disc 220 (see. Fig. 1 ) as a function of the dust hood type detected by the sensor unit 20.

The direction of rotation control electronics 230 is further formed, a rotation of the blade (see. Fig. 1 ), if - as in Fig. 2 shown - none of the dust hoods 100, 100 'are connected to the grinder 200.

The sensor unit 20, which has said on / off / on-toggle switch, is displaced with connection of the dust hood 110 with flushing connection 50 in a first on position and pressed at connection of the dust hood 100 with suction 40 in the second on position. If neither of the dust hoods 100, 100 'is connected to the cut-off machine 200, then the toggle switch not shown here is in the middle position, which prevents the cutting disk 220 from rotating when the cut-off wheel 200 is activated. This is effected by the appropriately established direction of rotation control electronics 230th

Fig. 3 shows a further preferred embodiment of a cutting grinder 200 according to the invention. The grinder 200 has at a Griffstirnseite GF a sensor unit 20, which has only a hood-type contact 27 in the form of a magnetic contact in the present embodiment shown.

The dust hood 100 with suction nozzle 40, which is shown above the cutting-off grinder 200, has as coding 110 a magnet embedded in the hood body.

When the dust hood 100 is connected to the abrasive grinder 200, the hood type contact 27 is operated in the form of a magnetic switch by the code 110 in the form of a magnet, i. electrically closed. The electrical closing of the magnetic switch is evaluated by the direction of rotation control electronics 230 in the sense of a sensor signal.

In the present embodiment, the direction of rotation control electronics 230 is set up, with attached dust hood 100, ie with closed magnetic contact, the cutting disc 220 (see. Fig. 1 ) to drive GGD in opposite direction.

Fig. 4 Finally, shows a further preferred embodiment of a cutting grinder 200 according to the invention. This has on its surface OF a sensor unit 20, which are provided in the present embodiment by a hood contact 25 and a hood type contact 27, each in the form of a discrete button.

The hood contact 25 and the hood type contact 27 functionally integrated, which will be explained in more detail below. The mechanical coding 110 on the dust hood 100 with suction nozzle 40 is set up to actuate the lower of the two buttons. The connection of a dust hood with flushing connection, which is not shown here, would activate the upper of the two buttons. In this respect, the two buttons act together as a hood type contact 27, based on the switching state, the direction of rotation of the blade is specified.

At the same time it is provided that if both buttons remain unactuated, so as in Fig. 4 shown, no dust cover 100 is connected to the grinder 200, the cutter 200 remains active when activated. In this respect, the buttons not shown here in more detail act synergistically also as hood contact 25, by means of which it can be detected whether a dust hood is connected to the cut-off machine.

Fig. 5 Finally, FIG. 3 shows a method according to the invention for operating a cut-off grinder, for example the cut-off grinder 200 described with reference to the previous figures. In a first step S1, detection is carried out by means of a sensor unit comprised by the cut-off machine, which type of dust hood is connected to the cut-off grinder. In a second step S2, a control of a direction of rotation of the cutting disk of the cutting-off grinder takes place as a function of the state detected by the sensor unit.

LIST OF REFERENCE NUMBERS

10

hood body

20

sensor unit

25

hood Contact

27

Hood Type Contact

40

suction

45

flap

50

Flushing connection

80

signal line

90

flange

100

Dust hood with extraction nozzle

100 '

Dust hood with flushing connection

110

Coding on the dust hood with extraction nozzle

110 '

Coding on the dust hood with flushing connection

200

Power Cut

210

transmission neck

220

cutting wheel

230

Direction of rotation control electronics

240

interface

400

suction

500

flushing hose

600

system

GF

Handle front side

GGD

opposite direction of rotation

GLD

synchronous direction of rotation

OF

surface

SL

sensor signal

S1, S2

steps

UG

Untergrundabtrag

Claims (10)

A cutting grinder (200) having a gear neck (210) for connecting a dust hood (100, 100 ') equipped with a flange (90),
characterized in that the cut-off grinder (200) has a sensor unit (20) by means of which it is possible to detect which type of dust hood (100, 100 ') is connected to the cut-off grinder (200), wherein the cut-off grinder (200) further comprises a direction of rotation control electronics (230 ), which is signal-connected with the sensor unit (20), such that the direction of rotation (GGD, GLD) of a cutting disc (220) of the cutting grinder (200) is predetermined as a function of the dust hood type detected by the sensor unit (20). A cutting grinder (200) according to claim 1,
characterized in that by means of the sensor unit (20) can be detected, if the dust hood (100, 100 ') connected to the cutting machine (200), wherein the direction of rotation control electronics (230) is further formed to prevent rotation of the cutting disc (220), if no dust cover (100, 100 ') is connected to the cut-off grinder (200). A cutting grinder (200) according to claim 1 or 2,
characterized in that the sensor unit (20) is arranged on a surface (OF) of the cut-off grinder (200), preferably close to the transmission neck (210). A cutting grinder (200) according to one of the preceding claims,
characterized in that the sensor unit (20) on a handle end face (GF) of the cutting grinder (200) is arranged. A cutting grinder (200) according to one of the preceding claims,
characterized in that the sensor unit (20) has a hood contact (25) by means of which it can be detected whether the dust hood (100, 100 ') is connected to the cut-off grinder (200). A cutting grinder (200) according to one of the preceding claims,
characterized in that the sensor unit (20) has a hood type contact (27) by means of which a preferably mechanical coding (110, 110 ') of the dust grinder (100, 100') connected to the cut-off grinder (200) can be read out. A cutting grinder (200) according to claim 4 or 5,
characterized in that the hood contact (25) and / or the hood type contact (27) in the form of a switch, a button, a magnetic contact or a light barrier is provided. A system (600) having a cut-off grinder (200) according to one of the preceding claims, and two dust hoods (100, 100 ') of different types, the type being each formed by a preferably mechanical coding (110, 110') provided by the sensor unit (20 ) of the cut-off grinder (200) can be read. A method of operating a cutting machine with a gear neck for connecting a dust cap equipped with a flange, the method comprising the steps of: - (S1) detecting, by means of a sensor unit included in the cut-off machine, which type of dust hood is connected to the cut-off machine, - (S2) controlling a direction of rotation of the cutting wheel of the cut-off wheel in dependence on the detected by the sensor unit state. Method according to claim 9,
characterized in that the step of detecting (S1) includes reading out a mechanical coding of the dust hood connected to the abrasive grinder.

Images