DE1539722A1 - Stimulation current therapy device - Google Patents

Description

Current stimulation therapy device The invention relates to a current stimulation therapy device with a generator for one of DC pulses, possibly with one additional direct current component, existing treatment current, which is supplied via electrodes is supplied to the body of a patient and after a selectable treatment time initially reduced to about zero, then reversed and slowly again after reversing is regulated up to treatment strength. The polarity reversal of the treatment current after a predetermined treatment time is required, otherwise the direct current any ion migrations that occur in the patient's body tissue can.

In the past, polarity reversal was carried out manually on these devices; for this purpose the doctor or an assistant had to go to one of a clock If the bell is triggered, regulate the treatment current down, the electrodes Use a commutator switch to reverse the polarity and then bring the current back to the required level Slowly increase the treatment strength. So it was for reversing the polarity of the treatment current the presence of a medically trained, relatively highly qualified assistant necessary.

at With the new therapy device, this is not necessary Presence of an assistant, if according to the invention for automatic execution these processes at a time that can be set on a timer in the path of the treatment flow a network with at least one controllable resistor iot provided by the timer is controlled by timers so that it disconnects the current path releases and blocks the current path at the set time and then again releases slowly, and if a relay influenced by the network is present, that actuates a commutator that reverses the polarity of the treatment current as soon as the current path has been blocked.

The essence of the invention is therefore that no auxiliary staff to carry out the various measures, namely downregulation, polarity reversal and slow Rules up in the right order and in the right way, more bendtlgt, but that these processes are completed on the command of the time switch proceed automatically. To this end lies according to the feature of the invention in the path of the treatment stream a network that on the command of the timer down regulates the treatment flow in the desired way first, then one Reversed polarity caused and finally the reversed treatment current slowly to the the desired final value.

In a practical embodiment of the inventive idea that has proven to be very expedient, there is the network that carries out the above task fulfilled in a satisfactory manner, according to a another char of the invention from two parallel-connected, each containing a controllable resistor Current paths, the controllable resistors being controlled so that in the idle state the first current path is enabled, the second current path is blocked and the Time switch at the same time the first current path within blocks a time t1 and slowly releases the second current path within a time t2, where t2 is large compared to t1, and is one which is influenced by the first current path Relay available, which actuates a commutator that reverses the polarity of the treatment atom, as soon as the first current path is blocked.

This embodiment of the invention, which has proven itself in practice, comes into play it comes down to it, at the command of the time switch, the first power wheel within a relatively short time, for example within one to two seconds, is blocked while the release of the second current path is taking place at the same time in contrast, takes a relatively long time, so that the second current path, for example is fully released only after ten to twenty seconds. Immediately after the complete blocking of the first current path is then the second current path released only to an insignificant extent, so that the network at this moment practically no treatment stream passes through, this point in time is taken from the network to reverse the polarity of the treatment current by actuating an appropriate commutator exploited.

Around In order to use the two current paths of the network in the To be able to reflect the described way, after a further development of the Invention put a T-link in each current path, the two longitudinal links of which are ohmic Resistors are and its cross member is the collector-emitter path of a transistor is. The base of this transistor is controlled in this way at the command of the timer. that the collector-emitter path either has a very high resistance or a assumes very low resistance.

If the resistance of the collector-emitter path is very high, it is affected they do not control the current path at all and the current path is for the treatment atom Approved. If, however, the base of the transistor is controlled so that the collector-emitter resistance is very low, the relevant current path is through the collector-emitter path practically short-circuited and the current path is blocked for the treatment current. The two ohmic series resistors are mainly used for mutual decoupling of the two current paths.

In order to follow the timing of the locking process outlined above to achieve the first current path as well as the slow release of the second current path, the bases of the transistors assigned to the two current paths must have a corresponding one Receive running control voltage. For this purpose, for example, in the Base circuit of each transistor an RC element can be provided, its capacitor the voltage at the base is determined and either via the one used as a charging resistor Resistance of the RC element RC element to a direct current potential placed or separated from it, the polarity of the direct current potential is chosen so that a base voltage with this polarity increases the conductivity of the collector-emitter line of the transistor increased.

The timing of the blocking of the first current path explained above and the simultaneous slow release of the second current path on the command the time switch is achieved in that the Gleiohstrompotential from which the Capacitor of the RC-Gliodes is charged, is large compared to the base voltage, those needed to keep the transistor completely open, d. H. to achieve a maximum Conductivity of the collector-emitter path is required, and furthermore that the resistance of the base-emitter path, which is dependent on the base voltage, is considered to be Discharge resistance of the capacitor in the RC element is involved. The resistance curve this base-emitter path thus contributes to the time profile of the blocking and the release of the current paths in an exemplary embodiment explained in the apGter resulting way.

The silicon transistor has proven to be particularly favorable for the purposes of the invention proven because its resistance characteristic of the base-emitter path in the so-called Threshold, which is at a base voltage of approximately 0.7 volts, of one relatively large resistance value very quickly into a small resistance value bends. In order to control the two current paths, one is preferred Execution area Example d.r invention the receipt of the two Transistors assigned to current paths via an RC element each to a fixed contact a single-pole switch operated by the time switch. According to one The commutator reversing the polarity of the treatment current can be implemented via a Pole-reversal relay are operated, the winding z. B. at the connection point of the series resistors that T-member is connected, the way in the first in the rest zone the treatment current releasing current path of the network is arranged.

Object. the invention is also a novel constructive Design of a sohaltuhr particularly suitable for the Zweske of the invention, the the command for polarity reversal is triggered at a set point in time as well as finally switches off the treatment current after a planned total treatment period.

Further features and possibilities of the invention and their mode of operation See from the embodiment of the invention explained with reference to the drawing.

Fig. 1 shows a schematically executed block circuit of a Exemplary embodiment of the therapy device.

Fig. 2 shows a schematic circuit diagram of a network in addition Time switch of the embodiment shown in FIG.

FIG. 3 gives those identified in the circuit diagram of FIG Corresponding voltage curves are shown again in a schematic representation. Fig. 4th Fig. 4 and 5 represent the embodiment of a timer for a therapy device after the invention.

In Fig. 1, 1 denotes a generator for pulsating Gleloh current. In the exemplary embodiment, the generator 1 consists of two in a voltage divider circuit connected to a mains transformer 7 for 50 Hz diodes 8 through which the alternating current is converted into half-wave pulses in accordance with the symbols entered in FIG. The generator 1 also contains a modulator in the form of a multivibrator, through which the pulsating direct current can be modulated in any way. Depending on whether one of the two phases or whether both phases of the alternating current after the rectification are used, either 50 Hz or 100 Hz pulse frequency are available for the treatment flow to the production.

The pulsating and possibly modulated one generated in the generator 1 Direct current is fed to a control device 2, which is controlled by means of the timer 16 triggered control pulses the automatic switching of the commutator 13 and the down and up regulation of the treatment flow accomplished at a predetermined point in time.

The commutator 13 is from a later to be explained in more detail, in the control unit 2 network via an amplifier 25 and a polarity reversal relay 26 actuated.

The circuit diagram of Figure 1 corresponds to the rest position of the device; the clock 16 is on the setting mark zero. Firmly connected to the movement 16 and A single-pole changeover switch 18 and an on-switch 17 are actuated by this How the two switches work Switch 17, 18 will be added later explained in more detail, it should only be said here that an on the network of the control device 2 connected Umsohalter 20 via the switching relay 19 from the Einsohalter 17 of the 16 o'clock is operated. At the same time as the control unit 2, a second control unit is also used 5 operated in parallel with 2, which is connected to a DC generator X. is.

Both generators 1 and 4 are connected to the treatment circuit via commutator 13 14, 15 switched so that when both generators 1, 4 are operated simultaneously in the Treatment circuit 14, 15 a pulsating direct current with an additional direct current component occurs. Each of the two types of current can be changed by a corresponding one Resistance 9, 10 metered and their intensity from separate display instruments 11, 12 can be read. There is also an amplifier 3, 6 for each type of current available, for example from a transistor amplifier and a power amplifier tube can exist.

In FIG. 2, one of the two control units 2, 5 is shown Networks together with the timer 16 and the switching elements operated by them shown in detail. The circuit of Fig. 2 represents the moment of hold of the single pole changeover switch 20 connected to the networks 2 and 5 of the fixed pole 46 to the remaining pole 47 and the resulting reversal of the treatment current by the commutator 13.

The network of the control device 2 consists of two current paths 32 and 33, in each of which there is a controllable resistor in the form of a one T-Giedes is located. The two longitudinal members of the T-joint each form a current path 32 and 33 two series-connected chemical resistors 36, 37 and 38, 39, and the Cross members are the collector-emitter paths 40, 41 and 43, 44 each of a transistor 30 and 31. At the bases 2 and 45 of the two current paths 32 and 33 assigned An RC element 34 and 35 is connected upstream of each of the transistors 30 and 31. Every RC element consists of two series-connected ohmic series resistors 21, 22 and 23, 24 of, for example, 22 ko or 150 ko and a cross-connected capacitor 66 and 67 of, for example, 100 µF each. The free ends of the series resistors 21 or 23 of the two RC elements 34 and 35 are connected to the poles 47 and 46 of the switch 20 connected.

The one provided for reversing the polarity of the treatment current at the electrodes 14, 15 Commutator 13 is actuated via amplifier 25 by polarity reversal relay 26. Of the Reversing pulse for polarity reversal relay 26 via amplifier 25 is sent to network 2 either at the connection point U1 or U2 between the two series resistors 36, 37 of the current path 32 or at the connection point between the fixed pole 47 of the monopolar Umsehalters 20 and the free end of the series resistor 21 of the RC element 34 removed. The network of the control device 5 is otherwise the network of the control device 2 designed completely the same.

The function of Netzwerkez 2 and 5 in their interaction with the other functional parts of the therapy device are briefly explained below.

So long As long as the fixed pole 46 of the switch 20 is closed, lies on the resistors 23, 24 and on the cross-connected Capacitor 67 (at point U1) has a positive DC potential.

This potential U1 is only 67 in the charge state of the capacitor a fraction (e.g., 2 volts) of the voltage supplied by the DC power source 27 (e.g. 8 volts). The relatively low charging voltage U1 across capacitor 67 comes from there comes about that the charging resistor 23 on the one hand and the Wlderstand 24 together with the base-emitter path 44, 45 of the transistor 31 on the other hand for the voltage 27 of 8 volts, for example, act as a voltage divider, so that the charging resistor 23 sets a voltage U1 of, for example, 2 volts. The potential U1 of the capacitor 67 is at the same time on the base 45 of a silicon transistor 31 and causes the point U3 has a very low potential of the pulse frequency, because the internal resistance the collector-emitter path 43, 44 of the transistor 31 with respect to the series resistors 38, 39 (at U1 # 2 V) is negligibly small and the entire from generator 1 supplied pulsating direct current practically via the collector-emitter path 43, 44 drains. It can thus over the resistors 39, 9 zero treatment current more flow in the direction of the treatment circle 14, 15, d. H. is the treatment current practically blocked for the current path 33.

For the current path 32, on the other hand, the opposite conditions apply to, because the via the RC element 34 with the base 42 of the of the transistor connected fixed pole 47 is open and thus de-energized, since this also causes the Base 42 of transistor 30 is dead, represents the collector-emitter path 4o, 41 represents a very high resistance to the series resistors 36, 97, see above that the entire treatment current supplied by the generator 1 in the direction of the treatment circuit 14, 15 drains.

As long as the fixed pole 46 is closed, the treatment current therefore flows only via the current path 32 to the patient, insofar as it flows through the network 2. As far as it also still flows through the network 5, namely when the pulsating Direct current from generator 1 is superimposed on a direct current from generator 4, is also in the network 5 for the direct current generator 4 only that current path for opened the treatment stream in the direction of the treatment circuit 14, 15, its associated Transistor with its base on the fixed pole 47 of the switch 20 is while the other current path is also blocked here for the treatment current.

When the clock 16 is wound up to sur setting mark 49, it sets during winding a well-known one firmly attached to the watch case Changeover switch 18 from the fixed pole 52 to the fixed pole 51. As soon as the Clock 16 expires and the setting mark 29 is reached, that is also on the clock 16 attached $ switch 17 turned on. At this clock position 29 is over the two switches 18 and 17 of the current through the switching relay 19 closed, which in turn, switches the changeover switch 20 from the remaining pole 46 to the fixed pole 47.

Now The one in the RC element 35 is now discharged Capacitor 67 slowly across the discharge resistor 24 and the base-emitter path 45, 44 of the transistor 31. The course of the discharge voltage across the capacitor 67 is shown in Fig. 3a. The charging voltage of U1 # 2 volts drops after the switchover moment ts at first relatively quickly, since the base-emitter path 44, 45 of the transistor 31 has a very low resistance value at the switching moment t5 and shortly thereafter. As soon as U1, however, down to the so-called threshold value of the base voltage of about 0.7 volts has dropped, the resistance of the base-emitter path 44, 45 becomes very high high, so that the discharge current of the capacitor 67 flows only slowly. Through this the voltage U1 runs fairly flat in the further part of the curve, i. H. the whole practically effective discharge time t2 of the capacitor 67 becomes quite long and amounts to in the example stable about ten to twenty seconds.

As a result of the slow decrease in the base voltage, the collector-emitter path 43, 44 of the transistor 31 a slow increase in the pulse voltage U3 (Fig. 3 b) causes.

The curve for U3 initially runs shortly after the switchover torque ts along the abscissa axis, so it is practically zero because of the resistance the collector-emitter path 44, 45 of the transistor 31 in the switching moment ts opposite the resistors 38, 39 is also practically zero. After reaching the Threshold voltage, the voltage curve for U3 rises slowly to its final value, since the collector-emitter resistor 43, 44 of the transistor org Transistor 31 has now assumed a very great value; the current path 33 is now released.

As soon as the arm 48 of the Umsehaltera 20 in the switching moment t8 the fixed When pole 47 touches, the capacitor 66 located in the RC element 34 is taken from the voltage source 27 charged via the charging resistor 21. As a result of the opposite to the threshold voltage of the transistor 30, the relatively high voltage of the voltage source charging the capacitor 66 27, the voltage U2 (Fig, 3 c) increases within a time compared to the discharge t2 of the capacitor 67 of e.g. B. ten to twenty seconds short loading time tl of z. B. one to two seconds quickly and goes after reaching the wool tension of the transistor 30 in a straight line parallel to the abazissa corresponding to z. B. 1 N 2 volts above. According to the rise time tl (Fig. 3c) of the base voltage U2 of z. B. one to two seconds duration is at the collector-emitter path 41, 40 of the transistor 30 an equally long decay time t1 of the collector voltage U4 up to practically the zero value causes (Fig. 3 d); the current path 32 is now blocked.

The decreasing or decreasing tensions according to Fig. 3 b or

Fig. 3 d combine at the input of amplifier 3 and are about the commutator 13 is fed to the treatment circuit 14, 15.

Since around time t for reasons to be discussed later the Commutator 13 reverses the treatment current, the voltage curve runs according to Fig. 3 b in the negative and the voltage curve according to FIG. 3 d in the positive voltage range of the treatment extremes current (Fig. 3 e,). In other words: before holding the changeover switch 20 from fixed pole 46 to 47 is the treatment current positive, after switching it is negative, namely, the treatment current becomes when the polarity is reversed by the commutator 13 not suddenly, but, as required, gradually switched off or on within about 1.5 or 15 seconds.

It can be clearly seen in Fig. 3e that the rise time t2 (Fig. 3 b) must be large compared to the decay time t1 (Fig. 3 d), so that the polarity reversal of the Treatment current at about tl if possible at U5 = zero (Fig. 3 e). In practice, a ratio of about 1 s 10 has proven to be expedient for t1 and t2 proven. Furthermore, it can be seen from the curve of FIG. 3 e that the not exponential, kinked rise in the voltage curve (Fig. 3 b) is beneficial has an effect than the voltage-free polarity reversal of the treatment current at about t1 is promoted. A polarity reversal of the treatment current with as little voltage or current as possible but should be aimed for for therapeutic reasons.

The commutator 13 is via the amplifier 25 and the polarity reversal relay 26 switched over at the moment when the voltage U4 (Fig. 3 d) is practically has dropped to zero. At this moment (around t1) the amplifier receives 25 a pulse that the response of the polarity reversal relay a6 and thus the polarity reversal of the Treatment current initiates through the commutator 13 connected to the polarity reversal relay 26; it does not matter whether the amplifier 25 is taking besides that Polarity reversal relay 26 on the collector-emitter path 40, 41 or on the base 42 of the transistor 30 or is coupled to the charging resistor 21 of the RC element 34.

As soon as the timer 16 has expired, according to the setting mark Zero (FIG. 2), the changeover switch 18 fixed on the clock 16 irt via the fixed pole 52 switched, thereby the positive DC voltage 27 is applied to the fixed pole 47 of the Switch 20. Due to the switching mechanism described above, this is the Current path 32 blocked for the treatment current. Since the fixed pole 51 is open, the switching relay 19 no longer receives voltage and sets the switching arm 48 to the fixed pole 46 un, as a result of which, as explained above, the current path 33 as well is blocked for the treatment stream. Since now both current paths 32 and 33 are blocked no more current flows in the treatment circuit 14, 15 either. However, as soon as the Timer 16 is wound up again. the changeover switch 18 is set to the fixed pole 51 turned over and thus initially, z. B. ten minutes, the current path 32 and then, e.g. B. for ten minutes, the current path 33 free or blocks within the current path 33 for the first ten minutes and within the further ten minutes the current path 32 for the treatment current.

All timer 16 can be used in a clock that is customary Way is equipped with a first contact set 18 (Fig. 4).

The clock is according to an embodiment of the invention with a second contact set 17 provided. This second set of contacts exists consists from two contacts 56 and 57, of which the first 56 on one on the shaft 55 is free movable bush 51 is attached, which is provided with setting marks. The socket 51 is by friction via two friction disks 65 on the mounting plate 54 of the device relative to the belm expiration of the timer 16 rotating shaft 55 held for as long. until the second contact 57, which is fixed on the shaft 55, hits the first contact 56. At this moment, the switch 17 is closed, which is in series with the switching relay 19 (Fig. 2) located resistor 50 short-circuited, so that the Switching relay 19 picks up and the changeover switch 20 connected to it from pole 46 to pole 47, whereby the above-described polarity reversal of the treatment current is initiated. As a result of the resistor 50, the switching relay 19 is also then held in tightening position when the conductivity between contacts 56. 59 as a result of impact or similar Causes is wholly or partially canceled.

The time ts of the polarity reversal process is set by turning the at the edge set with a knurled socket 51 on the number scale 52, z. B. from 0 to 2 (Figures 5 and 6). The total time of the treatment is shown by means of the button 60 set by rotating in the direction of the arrow according to FIGS. 5 a and 6 a. z. B. from O to 4. (Fig. 5 b and 6 b). Assume that the expiration tent of scale number increases If the number of dials is about five minutes, then in the example the clock is 16 at about A treatment time of twenty minutes is set. taking ablaur after about ten minutes the polarity reversal process Pole reversal is carried out automatically 0 Man further recognizes from Fig. 6 b that when the clock 16 is running in the direction of the pril, the contact 57 at about the scale number 2 hits the contact 56 and this with the socket 51 bis takes with it to the scale number zero (Figo 6 a).

Claims (14)

Claims 1.) Stimulation current therapy device with a generator for one of direct current pulses, possibly with an additional direct current component, existing treatment current, which is supplied to the body of a patient via electrodes is and after a selectable treatment time initially reduced to about zero. then the polarity reversed and, after the polarity reversal, slowly increased again to treatment strength is, characterized in that for the automatic execution of these processes to a point in the web of the treatment stream that can be set on a timer a network with at least one controllable resistor is provided, which is of the time switch is controlled by timers so that it disconnects the current path in the idle state releases and blocks the current path at the set time and then again releases slowly, and that there is a relay influenced by the network, that actuates a commutator that reverses the polarity of the treatment current as soon as the current path has been blocked. 2. Stimulation current therapy device according to claim 1, characterized gekennzeiohnest, that the network (2) provided by way of the treatment stream consists of two parallel switched current paths, each containing a controllable resistor (30, 31) (32, 33), the controllable resistors (30, 31) are controlled so that in the idle state the first current path (32) released, the second Current path (33), however, is blocked and the timer (16) to the set Time at the same time blocks the first current path (32) within a time tl and the second current path (33) slowly releases within a time t2, wherein t2 is large compared to t1, and that a relay is influenced by the first current path (32) (25) is present, which actuates a commutator (13) which reverses the polarity of the treatment current, as soon as the first current path (32) has been blocked. 3. Stimulation current therapy device according to claim 3, characterized in that that in each of the two current paths (32, 33) a controllable resistor in the form of a T-link, the two longitudinal links of which have chemical resistances (36, 37 and 38, 39) and whose cross member is the collector-emitter path (40, 41 and 43, 44) of one The transistor (30, 31) is connected to the base (42, 45) of the timer (16) via an RC element (34, 35) either the collector-emitter path (40, 41 and 43, 44) on one very high resistance value controlling potential or a collector-emitter path (40, 41 and 43, 44) on one opposite the unconscious of the longitudinal members (36, 37 and 38, 593 sets low resistance value controlling potential. 4. Stimulation current therapy device according to claim 3, characterized in that that the bases (42, 45) of the transistors assigned to the two current paths (32, 33) (30, 31) via one RC-Glled (34, 35) each to one fixed contact (46, 47) each single-pole changeover switch (20) which can be actuated by the timer (16), whereby the movable, with one the collector-emitter path (40,41 and 43, 44) of the transistors (30, 31) contact connected to a low ohmic value controlling potential (48) at rest on the fixed contact (46) for the base (45) of the at rest blocked, second current path (33) associated transistor (31) is located and from the Switch clock (16) to the other fixed contact (47) at the set time for the base (42) of the first current path (32) associated with the first current path (32) given in the idle state Transistor (30) is turned over. 5. stimulation current therapy device according to one of claims 3 and 4 thereby characterized in that the commutator (13) actuating polarity reversal relay (26) on the Connection point of the series resistors (36, 37) of that T-member (34) connected is that in the first in the idle state the path of the treatment flow is released Current path (32) of the network (2) is arranged. 6. stimulation current therapy device according to one of claims 3 and 4, characterized characterized in that the commutator (13) actuating polarity reversal relay (26) zit the fixed contact (47) of the single pole changeover switch (20) is connected to the base (42) of the transistor (30) for the first current path released in the idle state (32) of the Netzwtrku (2) is assigned. 7. stimulation current therapy device according to ins of claims 1 to 6, characterized characterized because # the commutator (13) actuating polarity reversal relay (26) via a Transistor amplifier (25) is controlled. 8. Stimulation current therapy device according to one of claims 1 to 7, characterized marked. that the network (2) between the generator (1) and an amplifier (3) for the treatment current and that the commutator (13) is at the output of the amplifier (3) is arranged. 9. Stimulation current therapy device according to one of claims 1 to 8, characterized characterized in that between the network (2) and the input of the amplifier (3) a control resistor (9) for metering the treatment current is 0 10. Stimulation current therapy device according to one of claims 1 to 9, characterized in that in addition to the first generator (1) for the direct current pulses a second generator (4) for an additional direct current component with a second variable resistor (10) and a second amplifier (6) whose Output to the first amplifier (3) is parallel, is present and that the second Generator (4) a second network (5) with at least one controllable resistor is connected downstream, the first with the first generator (1) connected downstream Network (2) agrees and with this synohron controlled by the timer (16) will. 11. Stimulation current therapy device according to claim 4, characterized gekennzeiohnet, that the single pole switch (20) from the timer (16) via a switching relay (19) is operated, the winding of which is in series with a power source (27) and with a the resistance (50) preventing the switching relay (19) from being picked up, the the timer (16) short-circuits at the set time. 12. Stimulation current therapy device according to one of claims 1 to 11, connected by using a timer (16) with two independently adjustable Contact sets (17, 18), of which the first contact set (18) is used to set the Time of shutdown and the second contact set (17) for setting the Time of polarity reversal of the treatment current is used. 13. stimulation current therapy device according to claim 1 to 12, characterized in that that the first set of contacts (18) of the timer (16) to the one for switching off the Treatment current set time the connection of the switching relay (19) interrupts with the power source and also one of the two current paths (32, 33) of the Network (2) or the networks (2, 5) blocking voltage to the controllable resistors (30, 31) of the network (2) or the networks (2, 5) sets, while the second contact set (17) at the time set for the polarity reversal of the treatment current short-circuits the resistor in series with the hold relay (19). 14. Stimulation current therapy device according to claim 12 and 13, characterized in that that the first set of contacts (18) formed by the contacts of a conventional timer (16) and the second contact set (17) consists of two contacts (56, 57), of which the first (56) on one on the shaft (55) of the Time switch (16) free movable bush (51) is attached, which is provided with adjustment marks and through Friction on a stationary part (5X) of the device compared to that when the Timer (16) rotating shaft (55) is held until the on the shaft (55) of the timer (16) fixed second contact (57) against the first contact (56) bother.