DE397739C - Protection fuse for electrical machines at risk from temperature increases, etc. - Google Patents

Description

GERMAN EMPIRE

ISSUE AMl. JULY 1924

REICH PATENT OFFICE

PATENT LETTERING

- JVe 397739 CLASS 21c GROUP 58

(D 37614

C. Loos & Co. in Essen-Altenessen. Protective fuse for electrical machines at risk from temperature increases, etc.

Addendum to patent 323369.

Patented in the German Empire on May 19, 1920. Longest duration: August 13, 1936.

In the case of protective fuses, which according to patent 323369 contain a fuse in parallel connection ¹ to a temperature fuse or an auxiliary S switch operated by the latter, there is the possibility in special cases that the protective fuse may not always be in the event of a defective fuse or a new fuse not being inserted is able to switch on the occurring current in an operationally reliable manner. This case can occur if the contacts of the thermal fuse or the auxiliary switch it actuates when the thermal fuse triggers at an insufficient distance from

are brought to each other so that the resulting arc cannot break off. The protection against inadmissible high heating is z. B. in engines, in the Usually only when the engine is running, so that only the disconnection of a differential voltage is required and the switch-off spark is therefore lower, on the other hand The shutdown can result in idle windings, especially in the case of ίο high self-inductions of the arcing that occurs at the contacts is not sufficient. Even if the replacement of the new fuse in The temperature protection device is usually done by a competent rope worker, because yes the cause of the high heating of the electricity consumer was initially determined and the the latter may have to be put out of operation for some time, so under certain circumstances However, it is desirable, especially with large engines, etc., to have a device on the protective fuse to meet the protective fuse in the event of a defective fuse or the absence of one makes ineffective. If such a measure were not applied, then at. a stopping of the arc, the protective fuse will be completely or partially destroyed, but would the disconnection of the power consumer as a result of a shock to the body the otherwise existing protection (circuit breaker, fuse) take place. Protection of the engine would have occurred in this way too, and now only a complete one would have to be Apply new protection & safeguards installed.

The locking of the temperature protection fuse or the auxiliary holder can now be done once in the cases mentioned, 4.0 that a special fuse is used, which mechanically effects the blocking in a defective state, furthermore, a blocking can be achieved mechanically in the absence of the fuse. Fig. 1 shows an example of mechanical locking when the fuse has blown. The fuse s is connected in parallel to the contacts k _v k ₂ of the switch influenced by the temperature fuse (not shown). The latter has a short piston c in its upper part, which is lifted up at the moment the fuse blows due to the gas pressure and, by lifting the lever Ii , prevents the contacts ^ ₁ , k _{2 from} reopening, even if the temperature sensors have responded again should, because the hose spring / causes the small piston to be held in place after the fuse has melted. The blocking of contacts £ ,, k ₂ is only released after a new fuse has been installed.

Another example of the blocking in the absence of the fuse is shown in Fig. 2. The fuse s is again parallel to the contacts k _t , k., Of the auxiliary switch. The supply line to the contact k \, however, is interrupted at the contacts C ₁ , C ₂ if, in the absence of the fuse, s is lifted by the spring / the movable contact piece C _1.

A useful blocking of the protective fuse, both in the case of an absence and a defective fuse occurs, consists in the circuit shown in Fig. 3 is.

There is a current branching in such a way that a circuit consisting of fuse s and auxiliary coil in is connected in parallel to the heating coil Ii. The contacts k _t , k _{2 of} the temperature fuse t are in series with the heating coil. The resistances of the heating coil h and the auxiliary coil m are dimensioned so that when the contacts are closed most of the current flows through the heating coil h , while only a small partial current through the fuse s and the auxiliary coil m, e.g. B. one tenth of the total current flows through it. When the normal operating current flows through the protective fuse, the auxiliary coil m excites a small magnet, which releases the thermal fuse. However, if there is no or a defective fuse in the device, the magnet cannot be excited and blocks the temperature fuse. This can be seen in more detail in Fig. 4. The heating coil h surrounds the temperature fuse with the soldering point at / and the 100 contacts k _lt k ₂ . The auxiliary coil m is used to excite a small magnet, the armature α of which is attracted when the current passes through the auxiliary coil, but is withdrawn by the spring / in the event of an interruption in the circuit, auxiliary coil and fuse, whereby the bent end of the armature a is located under the disk r lays. This makes it impossible for the no contacts k _lt k _{2 to be} opened even if the temperature fuse has responded.

Simultaneously with this blocking of the temperature protection device in the event of an interruption in the circuit of the fuse, a further locking device is shown in Fig. 4 see which comes into effect when the current strength exceeds a certain maximum value, z. B. in a short circuit, goes out. For such cases, as has already been pointed out, not the shutdown in the temperature fuse, but at another point of the Circuit done in the usual way. the

The thermal fuse is blocked in a threading-in manner in that the heating coil surrounds the thermal element at the same time as the core of a small magnet. The armature b of this magnet is pulled off the poles by a spring g and is only attracted when currents are twice to three times the normal current. The anchor end is bent over at r

ίο Blocking of the temperature fuse.

The devices connected to the same power supply unit will block it both when the current value is too high and when the power circuit in which the fuse is located is interrupted and is intended to actually switch off the endangered power consumer. The arrangements described above were made with the intention of preventing excessive arcing from occurring. These can only occur if, in some way, the actual shutdown would take place not through the fuse, but through the contacts ki, k ₂ . In such a case, the full operating voltage would have to be switched off under certain circumstances at the contacts ki, k _2.

With the help of a modified circuit, the emirection can now be met that due to the temperature detection not the whole Voltage, but only a small partial voltage interrupted by which then a fuse can only be brought into effect directly.

This can be seen in more detail in Fig. 5. As before, the heating coil h heats the temperature fuse ί with the soldering point at Z. The contacts / ei, k ₂ are short-circuited by, jthe temperature fuse in the idle state.

In parallel with the contacts ki, k _{2 there} is a second heating coil p which surrounds the fuse s in a manner known per se.

The fuse is not in this parallel circuit, but in series with the heating coil h. It should be dimensioned for the operating current or, if possible, ¹¹ for a current value above this, so that in the event of a short circuit it immediately switches off the current consumer. However, if the electricity consumer to be protected is at risk from gradual heating, the contacts k _lt k "will open as a result of the soldering of the soldering point at Z, through which the heating coil ρ is also switched into the circuit. This heating coil now spatially surrounds the fuse ί and heats it in such a way that it must burn out after a short time even at current values that are below the normal current. Because only the slight voltage gradient of the heating coil is interrupted at the contacts, the formation of an arc is avoided. In addition, there is the advantage that the same fuse is used both as protection in the event of brief 6g as well as in the event of prolonged overloading of the power consumer.

In Fig. 6 a deviation from the arrangement described above is made in that only one heating coil is used. The fuse s, which is mechanically connected to the temperature fuse, is in the idle state outside the effective range of the heating coil h. When the temperature fuse t has responded by soldering the soldering point at I i, however, the fuse is brought under the action of the heating coil h , so that the shutdown is initiated.

A further simplification of the circuit can be seen in Fig. 7.

The short circuit of the heating coil h takes place here through a two-metal strip 2 on the contacts ki, k ₂ . If excessive heating occurs, the two-metal strip ζ bends in the direction of the arrow, so that the current can now flow through the heating coil h , which lowers the melting point of the fuse due to the build-up of heat and causes it to switch off the circuit.

To ensure that the safety fuse is influenced as briefly as possible in the arrangements described last, a combination with the device according to patent specification 314474, as shown in Fig. 8, can be made. The combined maximum current and temperature release m, consisting of a lower part made of iron and an upper part made of non-magnetic material, contains the soldering point at I , after which the spring / upper part with the contact bridge b lifts off the contacts ki, k ₂ so that the heating coil ^ for the fuse j is switched on. In addition, the contacts ki, k ₂ open each time the entire temperature fuse m is pulled through the iron lower part into the coil h . So every current surge is transmitted directly to the heating coil / ", so that with larger current surges an increased heating effect occurs. This is equivalent to influencing the time constants for the entire protective device, which is very desirable because the thermal fuse often does not work fast enough with brief current surges .

Such an increased effect at relatively large currents can also directly affect the Thermal protection can be exercised in that certain current values depend on an additional heating coil is switched on

will. This enables the thermal fuse to respond more quickly at higher current values. For example, a circuit can be seen in Fig. 9. The temperature fuse f with the solder joint at Z is surrounded by the heating coil Ii and a second heating coil p , which is normally short-circuited by the contacts ei, C _2. However, if the current is too high, the iron core m is drawn into the coil h ^ and opens the short circuit of the coil p. Since it is only a question of the interruption of a small voltage gradient, the interruption of the contacts ei, C _{2 is} almost spark-free.

After the thermal fuse t has responded , the contacts ki, k _{2 are} opened and the fuse ä is switched on in the circuit, whereby the switch-off is _{effected after ao} some time.

In this arrangement too, the time constants are influenced. One more further dependence of the switch-off time on the respective current strength is achieved, if several heating coils are switched on intermittently.

In order for the described arrangements to be able to influence the If the fuse occurs, it is advisable to design it so that it absorbs good heat and forwarding takes place. For the same reason, it is also useful to higher degrees of warmth than can be achieved with normal cotton insulation for the heating coil can be allowed to. For this purpose, the heating coil is made of bare or oxidized Metal wire (e.g. copper, iron, aluminum) made with sufficient Distances for the individual turns iii refractory material is embedded. Through this it is also possible to use ordinary tin solder as soldering material for the soldering point of the temperature control.

Those in the process of switching off electromagnetic and similar devices are free magnetic energies are so great that high voltages and Arc phenomena occur. This can l> esoniders with large load magnets and the Fields of large motors appear, so that then under certain circumstances the for Shutdown certain, short-circuited by the thermal fuse in the idle state The fuse is not working reliably enough. In order to counter this problem, one now uses the magnetic winding to connect a protective resistor in parallel, j through which a compensation of the magnetic! Energy can take place. If this resistor is permanently connected in parallel, then so it represents a permanent, unnecessary additional burden. This is especially the case with larger ones Services where the resistance must be dimensioned correspondingly strong, taking into account the high current values that occur got to. It is also necessary to set the resistance directly next to the magnet to be protected to attach so that even with interruptions in the supply lines, z. B. in the magnetic cable, too it is possible for a load magnet to become inactive.

It is therefore appropriate, for. B. with a load magnet, the resistance in or on the Magnet housing to be attached in a suitable manner, as there is one in the driver's cage of the relevant In the vast majority of cases, crane's intended protective resistance is not at all effective can kick.

In the protection fuse of the invention, which is a fuse in combination with a thermal fuse built into the apparatus to be protected is used the desired protective measure is easily possible.

It is z. B. of canceling the short circuit of the fuse contact with the free end of the protective resistor so associated that shortly before the entry of the through melting of the fuse protection of the abutment Stanid g parallel to the magnetic coil is connected _0.

The circuit can be seen in Fig. 10. The coil Ii (e.g. the magnet winding of a load magnet) heats the temperature fuse t, which is activated at the hazardous temperature, e.g. B. 80 ° C, soldered on / so that the spring / removes the contact of s with k _x and creates a current connection at k ₂ . As a result, the protective resistance w, z. B. a silicon or carborundum resistor, connected in parallel with the solenoid. As the fuse.? is now switched on in the circuit, it will after some time, z. B. after one to two minutes, melt through if it was correctly dimensioned for the total current occurring. The released magnetic energy can safely balance itself over the resistance <w.

If the protective resistance is large, e.g. B. if it is equal to or less than the resistance of the solenoid coil, the fuse s can be omitted under certain circumstances, since the main fuses p _x and p ₂ take over their role and due to the high resistance w occurring after switching on the protective resistor, e.g. the double the total amperage.

Claims (13)

Patent Claims: i. Protection assurance for increased tenacity endangered electrical Machines, apparatus, lines or individual parts of such, according to patent 323369, characterized in that the cancellation of the short circuit of the fuse as a result of interlocking between this and the temperature sensor only in the case of current permeability of the fuse or of the entire short-circuit contacts to be used parallel .connected auxiliary circuit come into effect can. 2. Protective fuse according to claim i, characterized in that the locking of the Temperatursicfaerung when defective Fuse 'takes place through this itself (Fig. 1). 3. Protection fuse according to claim 1, characterized in that the lock in the event of a missing fuse on mechanical · or electrical Ways come into effect (Fig. 2, 3, 4). 4. Schutzicherunig according to claim 1 or 3, characterized in that the locking is achieved by an auxiliary sspule (m) which energizes a blocking magnet and is in series with the fuse (s) in the auxiliary circuit, the resistance ratios being chosen so that in normal operation only a small part of the total current flows through the auxiliary circuit (Fig. 3, 4). 5. Protection fuse according to claim 4, characterized in that the auxiliary circuit, consisting of fuse (s) and auxiliary coil (tu), is connected in parallel to the heating coil (h) and the heating coil has one or two poles when the short-circuit contacts open (^ ₁ , k ₂ ) is switched off with (Fig. 3, 4). 6. Protection fuse according to claim 1 or the following or according to patent 323369, characterized in that the cancellation of the short circuit of the fuse can only take place within a certain current range, beyond the effectiveness of the temperature fuse is canceled by locking becomes (Fig. 4). 7. Protection fuse according to claim 6, characterized in that the locking of the temperature fuse in the event of an interruption of the auxiliary circuit (by means of a) and when the current is too high (by means of b) by a common device (? ·) Is achieved (Fig. 4). 8. Protection fuse according to patent 323369, characterized in that the temperature fuse or the contacts of the Auxiliary switch influenced by the temperature fuse does not affect the fuse itself, but a heating coil is connected in parallel, which is in series with the thermal fuse Horizontal fuse is additionally heated after the thermal fuse has responded (Fig.s to 8). 9. Protection fuse according to claim 8, characterized in that; that a common heating coil (h) is used for the temperature control (t) and the fuse (s) and the latter is only brought into the area of the heating coil after the temperature fuse has responded (Fig. 6). 10. Protection fuse according to the preceding claims or according to patent 323369, characterized characterized in that the temperature fuse or the fuse surrounded by two or more heating coils are which, depending on the current intensity, are in effect individually or in groups and affect the time constant of the fuse (Fig. 9). 11. Protection fuse according to the preceding claims, characterized in that the heating coil made of bare or oxidized metal wire (e.g. copper, iron, aluminum) which is embedded in refractory material. 12. Protection fuse according to the preceding claims or according to patent 323369, characterized characterized by the thermal protection shortly after the removal of the Short circuit for the fuse, the activation of a parallel resistor to the winding to be protected is effected, so that the released magnetic energy is The safety fuse responds in a known manner via the protective resistor can compensate (Fig. 10). 13. Schutzicherunig according to claim; 12, characterized by such a dimensioning of the parallel resistance that, as a result of the increased total current that occurs, the main fuses (P ₁ , P ₂ , fusible links, circuit breakers, etc.) are activated in addition to or instead of the fuse (s) belonging to the protective fuse where the former fuse (s) can be omitted entirely. For this purpose ι sheet of drawings.