DE4119941A1 - Protecting drive motor of electrical power tool - controlling zero voltage releaser and excess current releaser by drive current - Google Patents

Abstract

The device is partic. for the motor of a portable drilling machine for concrete drilling, and protects against thermic overload. The temp. of a winding part of the drive motor (1) is monitored with a temp. probe (14). The temp. thus determined, after surpassing a predetermined limit value, brings about release and, after the temp. limit value has not been exceeded, switches on the zero voltage releaser (5). In a transition range between a value below max. permitted operating load and overload two control elements (18,19) produce indications, whereby with rising load the indication intensity of the first control element reduces and that of the second control element increases. USE/ADVANTAGE - Thermic overload protection for concrete drill driven by electric motor which does not involve complicated circuitry.

Description

The invention relates to a method for protecting an elec tric drive motor of a power tool that with a zero voltage release and with one through the receptacle current controlled overcurrent release is provided, esp special of a motor of a portable drill for driving concrete drills, against thermal over burden.  

Usually are used to protect drive motors ter power tools, especially of so-called core drilling machines, two-pole circuit breakers used, in which a common housing both the zero voltage release as well as the overcurrent release are housed. The zero The voltage release can be designed as a magnetic coil be that by means of a switching pin on an inner Shift lever acts. Works on the same gear lever in the same direction a bimetallic lever, which preferably from the up current is flowed through. Said shift lever be in turn makes two parallel contact pairs through an outer rocker switch can be actuated. By a be special switching mechanism is ensured that the inner shift lever also makes the contact pairs in the on Switch position of the rocker switch can open, and that further the contact pairs are not when the inner shift lever is actuated can be closed. The switching mechanism enables a so-called free release. Numerous variants of this Switch types are made by ETA Elektrotechnische Apparate GmbH in D-8503 Altdorf near Nuremberg / Germany under the group designation 3120-F. . . expelled.

The zero voltage release is used to protect the operator person in the event of a power failure: the power tool is running after resuming the operating voltage without one Switch actuation not on again. The overcurrent release serves to protect the drive motor against thermal Overload.

The switching behavior of the overcurrent release is characterized by so-called time / current characteristics, which are defined for each switch type, which in turn must be adapted to the drive motor. The relationships are explained in more detail below with reference to FIG. 3; it should only be noted so much at the moment that the total switch-off time drops rapidly with increasing intake current. The characteristic curve is in turn designed with regard to the maximum permissible winding temperature of the drive motor; however, it only takes into account the final temperature of the motor winding that - starting from a specified initial temperature for the motor and switch - is reached when it is switched on for the first time. Typical output temperatures for which the characteristic curves are defined for each switch type are -30 ° C, + 23 ° C and + 60 ° C.

It is also already known to drive motors from electrical works testify with a temperature instead of an overcurrent release to equip the sensor, which is housed in the motor winding is. This temperature sensor can, for example, be a component unit with a pair of contacts. For example, a such temperature switches contain a bimetallic disc, which has an erratic switching behavior. Such a However, the switch has a significant switching differential. There no warning before reaching the set limit temperature occurs, the temperature switch does not speak averages and sets the power tool for a long time out of service, this downtime easily May exceed 30 minutes.  

A ver with the circuit breaker described above Power tool can now be seen up to Destruction due to thermal overloading of the winding If the power tool is in accordance with the time / Current characteristic is operated under overload, then under the overcurrent release breaks when said Characteristic curve of the power tool circuit. Since the be said characteristic curve but the heating behavior of the drive motor, starting from given initial conditions, is the default when the overcurrent release trips Limit temperature of the motor winding at least essentially already reached. The time constant of the overcurrent release from switching off to switching on again is only about 5 to 10 seconds, which is its thermal inertia considerably is less than that of the motor winding. With others Words: While the characteristic of the overcurrent release is still in essentially the heating behavior of the motor winding simu lated, this is not the case with regard to the cooling behavior Case. So try the operator, the electrical plant after a response of the overcurrent release switch on again relatively short time, ge if necessary, even several times in succession, so it pumps in a way energy surges in the still under the mechanical load applied drive motor, whose Cooling additionally through significantly reduced speed or even standstill is reduced or interrupted. The The result is overheating of the drive motor, which without Warning can be operated until the winding is destroyed can.

The invention is therefore based on the object of protection to specify the method of the genus described at the outset, through the one without great circuit engineering effort Overheating of the motor winding can be prevented effectively can.

The task is solved at the beginning described method according to the invention in that the Temperature of a winding part of the drive motor with one Temperature sensor monitors and that of the temperature sensor certain temperature of the winding part after exceeding a predetermined temperature limit for triggering and, after falling below the temperature limit, to Switching on the zero voltage release used.

It is therefore a well-known circuit breaker Temperature limiter used, which does not have its own load switching con clocks needed, but to the already existing zero voltage release acts and in this practically voltage simulates looseness. So the operator pumps briefly early after the overcurrent release has tripped by repeated actuation of the device switch heat energy into the drive motor, so the true Ab image of the winding temperature from said temperature sensor detected and for actuating the zero voltage release used. The drive machine is stopped exactly as if there was a total power failure, and she is also when the temperature falls below the said limit not automatically switched on again, as is the case with Using a conventional temperature limiter  would be that directly on the circuit of the drive motor acts. The restart of the drive motor is therefore only if the following operations are performed at the same time possible:

• 1. The full operating voltage is present,
• 2. The winding temperature is below one predetermined limit,
• 3. the switch (main or device switch) is switched on the operator operated.

Such temperature sensors usually have a connection a switching difference with the associated switching element. It there are therefore two temperature limit values, namely one upper limit for switching off and a lower one Limit value for restarting (provided that the full operating voltage is present). This switching differential brings the additional advantage that the Motor winding can cool sufficiently before one Re-commissioning is possible.

It is particularly advantageous if you are in the course of a further embodiment of the protection ver driving detects the current of the drive motor and him on falling below or exceeding a specified current Limit value examined and if the value falls below the Limit a first control element and when exceeded a second control element for display  brings. In a particularly advantageous manner, the first Control element uses a light-emitting diode of the color "green" and as a second control element a light-emitting diode of the color "red".

The operator can, therefore, each time it is switched on immediately recognize the response of one of the control elements, whether the machine is in normal operation, i.e. H. when falling below of the nominal current, or is operated in the overload range. If the operator observes the relevant display, see above is only switched on if the following are observed Additional condition:

• 4. The current consumption is below the nominal current.

It is again particularly advantageous if you are in a transition range between a value below maximum permissible operating load (nominal load) and overload both control brings elements to the display, whereby with increasing load the display intensity of the first control element (green) gradually decreased and the display intensity of the second Control element (red) gradually enlarged.

The operator can therefore at the transition of the control color "green" to the control color "red" immediately recognize that the Drive torque and thus the current consumption increased. The relevant knowledge can be used, for example be applied, the feed or the contact pressure of the electric reduce tool.  

The invention also relates to an arrangement for carrying out the method described at the beginning with a zero voltage trigger and with a controlled by the intake current Overcurrent release.

Such an arrangement is to solve the same problem characterized according to the invention by at least one Temperature associated with the winding part of the drive motor sensor for recording the winding temperature, its output the zero voltage release is connected in such a way that when a specified temperature limit is exceeded switching off the zero voltage release and at Falling below the temperature limit and at the same time When the operating voltage is present, the Zero voltage release takes place.

According to a further embodiment, it is Invention particularly advantageous if in the circuit of Drive motor a current measuring element is arranged, the Input current proportional output voltage one Comparator is connected in which the measured value with a Setpoint is compared, and if the comparator two Has outputs, of which one output the first Control element for the display of the normal operating current and the other output to the second control element for the Display of the overload is activated.

The current measuring element can preferably be that of the absorption current flowed heating resistor for the overcurrent release be used, d. H. the bimetal switching element itself,  if the intake current flows through it.

The use of light emitting diodes as control elements is especially advantageous because these with Low voltage can be operated, no wear and show no aging and in the event of breakage the Cover pose no danger to the operator.

This is especially the case when the LEDs are over one optocoupler each with the respective output of the Kompa rators are connected and if for the generation of the Be drive current of the LEDs in addition to a first Trans second for generating the control voltage Transformer is present, which acts as an isolating transformer compared to the LEDs.

Further advantageous refinements of the counterpart of the invention status result from the other subclaims.

An embodiment of the subject matter of the invention is explained in more detail below with reference to FIGS. 1 to 4.

Show it:

Fig. 1 is a block diagram of the complete circuit or arrangement of a power tool constructed as a core drill,

Fig. 2 shows the essential elements of the control block of Fig. 1,

Fig. 3 is a time / current characteristic of the circuit breaker shown in Fig. 1, and

Fig. 4 is a graphical representation of the display intensity of the first and second control elements.

In Fig. 1, an electric drive motor 1 of a core drilling machine is shown, from which further details such as gear, drilling spindle and the diamond-tipped drill bit are omitted for the sake of simplicity. The entire circuit arrangement, described in more detail below, is integrated in the core drilling machine. The connection to the network is made via a three-wire cable 2 and a plug 3 , which can only be inserted into the associated socket in the specified pole positions L, N and PE (CEE plug).

An essential part of the circuit arrangement is a two-pole thermal circuit breaker 4 , which is a product of the company ETA Elektrotechnische Apparate GmbH with the group name 3120-F. . . acts. This circuit breaker has a different feature from the list version, which will be discussed in more detail below. The circuit breaker 4 has a zero-voltage release 5 with a magnetic coil 6 , which acts on a switching mechanism via a switching pin, not shown, which ultimately actuates the two parallel contact pairs 7 and 8 .

The circuit breaker 4 also has an overcurrent release 9 , the essential element of which is a bimetallic switching element, not shown, which is heated by direct current flow through the receiving current. This forms a resistor 10 , which was at the same time as a heating resistor and serves as a current measuring element for the input current of the drive motor 1 . Both the zero voltage release 5 and the overcurrent release 9 act in the manner described above be on a switching lever, not shown, on the contact pairs 7 and 8 , in such a way that a final as well as a voltage failure and when an overcurrent occurs Shutdown takes place, which can only be canceled by the operator when the operating conditions described above exist. A built-in free release, which is also not shown, ensures that switching off takes place even when the rocker switch is pressed, and that switching on is not possible as long as the switch-on conditions described do not exist. A light-emitting diode 11 is used to indicate the operational readiness of the power tool.

The essential difference between the circuit breaker 4 and the list-like design is a tap 12 between the contact pair 7 and the resistor 10 , which is fed to a switching block 13 as a measuring line M. The lines L and N continue to be supplied to this switching block, ie mains voltage, provided that the contact pairs 7 and 8 are closed. From switch block 13 , an output A leads to said drive motor, the other pole of which is connected to line N.

A winding part of the drive motor 1 is assigned a temperature sensor 14 which has a pair of contacts 15 which is opened by a bimetallic element, not shown, after an upper limit temperature has been exceeded and is automatically closed again after a lower limit temperature has been undershot. Such temperature limiters are commercially available, for example under the name "Clixon".

The temperature sensor 14 is used to detect the winding temperature and is in the same circuit 16 in which the solenoid 6 of the zero-voltage release 5 is located. Since the output 14 a of the temperature sensor 14 is connected to the zero-voltage release 5 via a line 16 a. This has the result that when the upper temperature limit is exceeded, the drive motor is switched off by the zero voltage release and when the temperature falls below the lower limit (and the operating voltage is present) the zero voltage release is switched on again. The zero-voltage release is therefore the switching element for the current consumption of the drive motor at the same time, while only the control current for the solenoid 6 is conducted via the contact pair 15 .

The switching block 13 is connected to an operating hours counter 17 and to a first control element 18 , which is designed as a green light-emitting diode, and with a second control element 19 , which is designed as a red light-emitting diode.

Further essential details of the switching block 13 are shown in FIG. 2. The power supply to the drive motor 1 takes place in the manner already described via the lines L and N. In this circuit is the resistance 10 through which the absorption current flows. These details are not repeated in FIG. 2.

The line L leads via a line branch to a first current source 20 and to a second current source 21 , both of which are designed as transformers with rectifiers, in order to generate a suitable control voltage. At least the second current source 21 is designed as an isolating transformer, which will be discussed in more detail below.

The connections of the current measuring element 10 on both sides detect a potential difference which is proportional to the absorption current and which is applied to a comparator 23 via an amplifier 22 . The amplifier 22 receives its operating current from the current source 20 . In the comparator 23 , the output voltage of the amplifier 22 is compared with a target value which corresponds to the limit value between the normal operating load of the drive motor and an overload. The normal operating range is between two lines 24 and 25 parallel to the abscissa (time axis), of which the lower line 24 corresponds to the no-load current. Overload line is above line 25 . The comparator 23 has two outputs 26 and 27 , of which one output 26 is the first control element 18 (green) for displaying the normal operating current and the other output 27 is connected to the second control element 19 (red) for displaying the overload.

The control elements 18 and 19 are each connected via an optocoupler 28 and 29 to the respective output 26 or 27 of the comparator. The transformer 21 used to generate the operating current of the light-emitting diodes is designed as a so-called isolating transformer. By means of this isolating transformer and the optocouplers 28 and 29 , the control elements or light-emitting diodes are completely electrically isolated from the mains voltage part of the switching block 13 , which is indicated in FIG. 2 by the dashed curve in the right part of the circuit diagram.

The switching block 13 is preferably formed by a uniform printed circuit board. All the components of FIGS. 1 and 2 are preferably housed in a common housing, which is attached with its operating and control elements in such a manner on the drive motor or the power tool that good observation is possible ensured for the operator. In the event that this housing should be damaged in the area of the control elements, the display part is not live, so that there is no danger to the operator if, for example, he actuates the rocker switch of the circuit breaker located near the control elements (LEDs). The other advantages of using light-emitting diodes have already been mentioned above.

In Fig. 3, the abscissa symbolizes values relative to the nominal current. No numerical values have been given, since equipping the drive motor with an appropriate circuit breaker can be very diverse. Conventional tripping times of such circuit breakers are plotted on the ordinate in seconds. The vertical dashed line 30 characterizes the idle current. It goes without saying that the switching block 13 contains a starting current limiter, not shown here, which includes a starting resistor and a switch bridging this resistor, which is actuated by a timer which closes the switch, for example, after 0.6 seconds.

The right dash-dotted line 31 characterizes the nominal current at which the power tool can be operated in continuous operation. On the right-hand side of line 31 is the so-called overload range, in which, depending on the size of the overload, the drive motor is switched off earlier or later. This switch-off behavior is characterized by the time / current characteristic curve 32 already discussed, which essentially simulates the heating behavior of the winding of the drive motor. Below the maximum permissible operating load according to line 31 , a transition area 34 is delimited by a line 33 parallel thereto, which is defined by the design of the comparator 23 . Here, the design of the comparator 23 expediently proceeds such that both control elements 18 and 19 are displayed in the transition region 34 , the display intensity of the first control element 18 gradually being reduced with increasing load and the display intensity of the second control element 19 gradually increased.

The course of the display intensities of the two control elements 18 and 19 is illustrated in FIG. 4. Until the transition region 34 is reached , the control element 18 has the full display intensity, ie in the given exemplary embodiment the light-emitting diode lights up at full brightness. Beyond the transition region 34 , the second control element 19 has the full display intensity, ie the red light-emitting diode present in the exemplary embodiment has the full light intensity. Within the transition region 34 - with increasing load - the display intensity of the first control element 18 is gradually reduced and the display intensity of the second control element 19 is gradually increased. This is indicated by the line 35 running obliquely in the transition region 14 between the horizontally and vertically hatched regions 18 a and 19 a. One preferably makes use of the mode of operation of the comparator: The input voltage of the comparator 23 has a certain residual ripple, the frequency of which corresponds to the mains frequency. Corresponding amplitude components are now decreasing or increasing above and below the preset target value in the predetermined transition range. This creates a kind of dimmer effect in relation to the light-emitting diodes that are triggered. The operator can thus recognize at an early stage when they enter the transition area with increasing engine load and leave it when entering the overload area. With appropriate attention of the operator, it can thus be prevented that the temperature limiter responds with the temperature sensor 14 at all. This enables a very extensive utilization of the normal operating range without long waiting times, which are caused by the cooling behavior of the drive motor and by the switching difference of the temperature limiter.

Claims (12)

1. A method for protecting an electric drive motor ( 1 ) of a power tool, which is provided with a zero voltage release ( 5 ) and with an overcurrent release ( 9 ) controlled by the absorption current, in particular a motor of a transportable drilling machine for driving concrete drills, against thermal overload, characterized in that the temperature of a winding part of the drive motor ( 1 ) is monitored with a temperature sensor ( 14 ) and the temperature of the winding part determined by the temperature sensor after exceeding a predetermined temperature limit value for triggering and, after falling below the Temperature limit value used to switch on the zero voltage release ( 5 ). 2. The method according to claim 1, characterized in that one detects the absorption current of the drive motor ( 1 ) and examines it for falling below or exceeding a predetermined current limit value and when the limit value is undershot a first control element ( 18 ) and If the limit value is exceeded, a second control element ( 19 ) is displayed. 3. The method according to claim 2, characterized in that in a transition area ( 34 ) between a value below the maximum permissible operating load and overload, both control elements ( 18 and 19 ) are displayed, the display intensity of the first control element ( 18 ) gradually reduced and the display intensity of the second control element ( 19 ) gradually increased. 4. Arrangement for performing the method according to claim 1 with a zero voltage release ( 5 ) and with a controlled by the input current overload release ( 9 ), characterized by at least one winding development part of the drive motor ( 1 ) associated temperature sensor ( 14 ) for detecting the winding temperature , whose output ( 14 a) the zero-voltage release ( 5 ) is switched on, such that when a predetermined temperature limit is exceeded, the zero-voltage release ( 5 ) is switched off, and when the temperature falls below the limit and the operating voltage is present, the zero-voltage release is switched on again ( 5 ) is done. 5. Arrangement according to claim 4, characterized in that the zero voltage release ( 5 ) is a magnetic switch with a conductor circuit ( 16 ) which can be interrupted by the temperature sensor ( 14 ) and closed again. 6. Arrangement according to claim 4, characterized in that the overcurrent release ( 9 ) is a thermally heatable by the receiving current breaker. 7. Arrangement according to claim 6, characterized in that the overcurrent release ( 9 ) has a resistance-heated bi-metal switching element. 8. Arrangement according to claim 7, characterized in that the heating resistor ( 10 ) of the bimetallic switching element has a tap ( 12 ) for determining the current consumption of the drive motor ( 1 ). 9. Arrangement according to claim 4, characterized in that a current measuring element ( 10 ) is arranged in the circuit of the drive motor ( 1 ), the output current proportional output voltage to a comparator ( 23 ) is switched on, in which the measured value is compared with a desired value , and that the comparator has two outputs ( 26 and 27 ), of which one output ( 26 ) to the first control element ( 18 ) for displaying the normal operating current and the other output ( 27 ) to the second control element ( 19 ) for display the overload is applied. 10. The arrangement according to claim 9, characterized in that the heating resistor for the overcurrent release ( 9 ) is connected as a current measuring element ( 10 ). 11. The arrangement according to claim 9, characterized in that the control elements ( 18 , 19 ) are out as LEDs. 12. The arrangement according to claim 11, characterized in that the LEDs are each connected via an opto-coupler ( 18 , 29 ) to the respective output ( 26 or 27 ) of the comparator ( 23 ) and that for the generation of the operating current of the LEDs In addition to a first transformer ( 20 ) for generating the control voltages, a second transformer ( 21 ) is provided, which is designed as an isolating transformer with respect to the light-emitting diodes.