NO137126B - PROCEDURE FOR COLD EXTENSION OF PRESSURE CONTAINERS. - Google Patents

Abstract

Procedure for cold drawing of pressure vessels.

Description

Step couplers, especially for lifts.

The present invention relates to a tap-changer, which tap-changer is assigned to a track length or section which is divided into zones, and contains static switching elements and on which signals in a signal series act, which signals are produced by signal generators, and which tap-changer is particularly intended for use by elevators.

A step switch with static elements for controlling lifts is known, in which each stop is assigned to a control unit, whereby the output state of a control unit which is affected by the control signal represents the position or position of the compartment. When the compartment's position changes, the control signal not only changes the output value of the following control unit, but also the output value of the left control unit. Consequently, the output values of the control units below and above which are affected by the signal are equal. However, this prevents the output values of the control units from being directly used to determine the direction of movement.

It is the purpose of the present invention to provide a tap-changer which, with as few as possible and with uniform static elements, makes it possible to determine the tap-changer's position or position, but which also emits output values that unambiguously determine whether the tap-changer is located below or above a certain position, which for example is absolutely necessary for determining the direction of movement. This is achieved by each zone being assigned a zone unit consisting of a memory element comprising two static elements, and two upstream static elements, which memory element is arranged to store and emit signals, whereby the one static element in the memory element is affected by the output signal from the first pre-connected static element and the second static element of the memory element are influenced by the output signal from the second pre-connected static element or from a reset transducer, to return the tap-changer to its output state, while a first input of one or both pre-connected elements is influenced by the signal from the signal generator which produces the signal series, another input is affected by a tap-changer limiter and a third input is affected by one of the outputs of the previous or the following zone unit's memory element, whereby an additional are inputs that act on these elements and determine the tap-changer's direction of movement, and that the output from the two static elements in the memory element on the one hand act as mutual inputs and on the other hand act on static position elements.

Another feature of the object of the invention is that the corresponding outputs of neighboring zone units which influence each other, act on a static element whose output indicates the position of the tap changer.

In order to prevent the tap changer with a signal from switching or moving several steps, it has been proposed to provide a delay or additional memory element for each control unit. According to the invention, this use of additional elements can be avoided in that a tap-changer limiter which is affected by the signal from the signal generator, by the position elements and by the direction of movement, affects the zone units in such a way that the tap-changer with a signal from the signal generator only moves one step.

In the event of a power failure, too low a voltage, etc., it may happen that the tap-changer no longer corresponds to the predetermined signal sequence, which results in a disturbance of the device to be controlled. In order to automatically cancel these disturbances, the tap-changer suitably has a device which is dependent on the direction of movement, and whose output signal acts on the tap-changer in such a way that it moves to the corresponding output position.

The attached drawings show an example of application for a lift system with examples of execution for the tap changer according to the invention. Fig. 1 shows a lift system where the lifting height of the compartment is divided into signal zones. Fig. 2 shows a step switch limiter for a step switch with the opposite directions of movement. Fig. 2a zone units and corresponding position and signal elements for a tap-changer with two opposite directions of movement. Fig. 3 and 3a the diagram for a floor control. Fig. 4 a further part of the lift control. Fig. 5 a static element in the form of an "neither-or"-connected transistor.

Fig. 6 a signal element.

Fig. 7 a step switch limiter for a step switch with one direction of movement, and

fig. 7a zone units and corresponding position and signal elements for a tap-changer with one direction of movement.

In fig. 1 is denoted by 20 a hoist compartment which, by means of a steel wire rope 21 over a drive axis 22, is connected to a counterweight 23. The drive disc 22 sits on the slow-running shaft of a drive 27 which is driven by an induction motor Mo. A brake B is built in between the drive 27 and the motor Mo, which is maneuvered with a magnet MB.

Compartment 20 serves stops 11—

15. The stops are equipped with call buttons DA 11—15. In the compartment 20 are placed contact buttons DC. On the compartment 20 there is a signal generator in the form of an induction coupler JS with a primary winding 24 and a secondary winding 25. The alternating current-fed primary winding 24 causes an output alternating current in the secondary winding 25 across an air gap, and this current is converted in a known manner in a rectifier to a direct current signal. In the shaft, fins Fil-F15 are fixed which, when the compartment 20 passes by, project into the air gap in the induction switch JS and interrupt the direct current signal, whereby a signal line is created. Furthermore, a sliding track 26 is placed on the compartment 20 which affects two switches ESd and ESu which

located at final stops. When the limit switch ESd or ESu is activated by the sliding path 26, an output signal 0 occurs here.

Fig. 1 further shows that the lifting height is divided into n-1 zones, where n denotes the number of stops. Each zone is assigned a in fig. 2a described zone unit with outputs Zc and Zd. The solid line corresponds to a signal value equal to 1 and the dashed line to a signal value equal to 0, with the value 1 of the element Zc denoting the section under the corresponding tab F to the lower end stop, and the value 1 of the element Zd denoting the section from the corresponding tab F to the upper end stop. A signal value is denoted by 1 or 0, when there occurs on the corresponding conductor resp. a voltage does not appear against a reference potential. The movement of the induction coupler JS from a tab F causes a change in the output values of the corresponding zone unit. Since the movement out from the tab F triggers a signal change, the location of this change for the upward movement u and the downward movement d is different, as can be seen from fig. 1. In order to be able to determine the position of the compartment, a further element is used, a so-called position element or position element Pe, as shown in fig. 2a, which each utilize the output value of two neighboring zone units. The output values of the position or position elements are represented by the lines Pli, P12, etc. It appears from the following description that the output values of the zone units are also used to determine the direction of movement.

To describe the tap changer according to fig.

2 and 2a, it is assumed that the compartment is located

at stop 11. Furthermore, the control example is based on a static element which provides an output signal 1 when all input signals show the value 0, and which

produces an output signal 0 when at least one input signal gets the value 1. This static element is generally referred to as an "neither-or" element. The tabs F are set so that the corresponding tab is located in the air gap of the induction switch JS when the coupe is at a stop. As a result, the secondary winding 25 provides no signal, i.e. JS = 0.

The induction switch JS is according to fig. 2 by means of a conductor LJS connected to an element 30, the output of which acts on a conductor L30. Depending on the direction of movement of the compartment, the floor control, as shown in fig. 3a, movement direction signals on the conductors LFub for the upward movement and LFdb for the downward movement. The conductor LFub leads to the first input terminal of an element 35 of a memory element MF. The conductor LFdb is connected to the first input terminal for the second element 34. The output voltage from the element 35 is applied to another input terminal for the element 34 and a conductor L 35. The output voltage from the element 34 serves as a second input voltage for the element 35 and further acts on a conductor L 34 .

An element 40 is connected to three input conductors LP11, LP13 and LP15, which come from corresponding positioning elements Pe, described in connection with fig. 2a. Output terminals of the element 40 are connected to the first input terminal of an element 41, the second input terminal of which is connected to a conductor L35.

In the following, for the sake of simplicity, the designation "input" shall be used both for "input terminal" and "input conductor" as for "input voltage" or "input current", while the term "output" is used analogously.

An element 36 exhibits two inputs LP12 and LP14, which come from corresponding position elements Pe. The output of the element 36 serves as the first input for an element 37, the second input of which leads to the conductor L34. The output of element 37 acts on the first inputs of elements 38 and 42. The other inputs of these elements lead to the output of element 41. The third input of element 42 is connected to the conductor LJS. The output of element 42 feeds the first input of one element 45 in a memory element MSB. The output of the element 38 is connected to the first input of the element 39 and its second input with the conductor LJS. The output of the element 39 acts as the first input for the second element 46 in the memory element MSB. The output from element 45 is connected partly to the second input of element 46, and partly to conductor L45. The output of element 46 leads partly to the first input of element 45 and partly to a conductor L46. The described elements 36-42 and the memory element MSB represent the so-called step switching limiter, which is denoted by SB in fig. 2.

The tap-changer is advantageously provided with a correction device which allows the tap-changer to be brought to the corresponding starting position at the stops when the coupling is disturbed by external influences. The correction device consists of elements 43 and 44. The output of the limit switch ESd leads over a conductor LESd to the first input for the element 43. A conductor LFda coming from the floor control (fig. 3a) acts as a second input for the element 43, whose output serves as third input for elements 45 and 46. Element 44 disposes of inputs LFua and LESu, whose output is connected as fourth input to elements 45 and 46.

The coupling according to fig. 2a shows partly (n-1) zone units with designations Z11 to Z14 and partly the position units that correspond to the floor number and which are denoted by Pe. A zone unit Z is composed of a memory element M with elements Zc and Zd, and with corresponding pre-connected and movement-dependent elements Za and Zb. A position unit consists of a position element Pe and a signal element PS.

The elements Za and Zb normally have four inputs. The first input is connected to the conductor L30. The second input for the elements Za and Zb, whose numerical index is an even number, is connected to a conductor L45, and the other input of these elements Za and Zb, whose numerical index is an odd number, is connected to the conductor L46. The third input of the elements Za is connected to the conductor L35 and the third input of the elements Zb is connected to the conductor L34. The fourth input of the elements Za leads to the output of the corresponding elements Zc, whose numerical index is 1 less, and the fourth input of the elements Zb to the output of the corresponding elements Zd, whose numerical index is 1 greater. As the zone unit Z11 is not connected upstream to any other zone unit and the zone unit Z14 is not connected downstream to any other zone unit, a fourth input is missing at the element Zall or at the element Zbl4.

Within the same zone unit, the elements are connected as follows: The element Zc has two inputs. The first input is connected to the output of the element Za, and the second input is connected to the output of the element Zd. The element Zd likewise has two inputs, the first input leading to the output for the element Zb and the second input to the output for the element Zc.

The position elements Pe dispose of two inputs. The first input is connected to the output for the element Zd with the same numerical index, and the second input to the output for the element Zc with the numerical index reduced by 1. The output for element Zc or Zd further also leads to corresponding conductors LZc resp. LZd. The element Pell has only one input, because the zone unit Zll is not connected to any other zone unit. Likewise, the element Pel5 shows only one input, because there is no zone unit with the same numerical index. The exit for. the elements Pe lead partly to the corresponding conductor LP with corresponding numerical index, and partly to a corresponding signal element PS.

However, the already mentioned correction device for the tap-changer can also directly affect the zone units Z, as the output for the element 43 acts as a third input for the element Zd and the output for the element 44 as a third input for the element Zc.

The floor control according to fig. 3 and 3a are provided with compartment push buttons DC, which are fed via a safety circuit SS, described in fig. 4, and over an auxiliary contact KB of the brake B. In addition, there are external call push buttons DA, the number of which corresponds to the number of stops and whose supply leads over a floor contact KF which disconnects the push buttons DA when the compartment is loaded. The signal from the safety circuit SS is carried on over conductors LSS to the input of an element 50 whose output signal feeds the conductor L50. This output signal has the task of erasing the memory elements MS (fig. 3) and MP (fig. 3a) in the floor control, when the safety circuit SS is interrupted. Each stop is provided with a memory element MS consisting of elements Sa and Sb. Each element Sa disposes of three inputs. The first input is connected to the corresponding push button DA, the second to the corresponding push button DC, and the third to the output of the assigned element Sb. The element Sb has a first input which leads to the output of the assigned element Sa. In addition, the element Sb still has two inputs for erasing the memory element MS. One input is connected to conductor L50 and the other to the corresponding conductor LP.

From fig. 2 and 2a shows that the position of the compartment is determined through the position element Pe. In order to enable movement of the compartment, additional elements are needed to be able to determine the direction of movement of the compartment. These elements must be able to determine whether a call is above or below the compartment position. For this purpose, elements Fg, Fh, Fi, and Fk are arranged. Elements Fg and Fh serve to determine the downward movement, and elements Fi and Fk to determine the upward movement. The elements Fg and Fi are dependent on the floor and are provided with a numerical index, as it must be taken into account that an upward or downward movement can only be made from (n-1) stops.

Each element Fg disposes of two inputs, one of which is connected to the output of the corresponding element Sa and the other to the corresponding conductor LZc. The outputs of the elements Fg serve as inputs for an element Fh, whose output acts on a conductor LFh. Each element Fi disposes of two inputs, the first of which leads to the corresponding output for the element Sa and the second to the corresponding conductor LZd. The outputs of the elements Fi serve as inputs for the element Fk, whose output is connected to a corresponding conductor LFk.

The signals in the conductors LFh and LFk must be held back during the movement until the tab F at the target stop interrupts the signal from the induction switch JS, as shown in fig. 3a. The downward signal in the conductor LFh is given as an input to an element 51, the output of which serves as an input for an element Fda and an element 52. The element Fda forms part of the memory element MFd which consists of an element Fda and an element Fdb. The output for the element Fdb is connected to the second input for the element Fda, and the output for the element Fda to the first input for the element Fdb.

The upward signal on the conductor LFk is supplied to an element 54, whose output serves as the first input for an element Fua, and as a second input for the element 52. The element Fua forms part of the memory element MFu which consists of elements Fua and Fub. The output for the element Fub is connected to the second input for the element Fua, and the output for the element Fua to the first input for the element Fub. The third input to the element 52 is formed by the conductor LJS. The output for this element 52 leads on the one hand to an element 53, and on the other hand to the other input for elements Fdb and Fub. The output of the element 53 acts on a conductor LMV. The elements Fdb and Fub have a third input which is connected to the conductor L50. The fourth input for the element Fdb leads to the output for the element Fub, and the fourth input for the element Fub to the output for the element Fdb. These two connections form a mutual locking of the movement direction memory elements MFd and MFu, which prevents both movement directions from being called at the same time. The output for the element Fda or Fua also acts on a leader LFda or LFua, and the output for the element Fdb resp. Fub on a conductor LFdb resp. LFub.

The motor Mo for the operating part is, as shown in fig. 4, fed from a network RST over movement direction relays Su and Sd. The primary winding of a transformer Tr is connected to conductors S and T, while the secondary winding on one side leads to a rectifier Gl and on the other side over the conductor 67 to the primary winding 24 for the induction switch JS. One output for the rectifier Gl is connected to a conductor L60 which is grounded, and the other output to a conductor L61. The two conductors L60 and L61 feed the control St, as shown in fig. 2, 2a, 3 and 3a. The pulsating direct current on the secondary side of the rectifier Gl is equalized in a known manner. The inputs LJS, LESd, LESu and LSS lead to the controller St. The purpose of the first three entrances has already been mentioned. The conductor L61 is connected to a safety circuit SS consisting of a catch device contact KJ, a stop button DH and door contacts KT. The output for the safety circuit SS leads partly over a conductor LSS to the control St, and partly over contacts KV for the door locking control to a conductor L63. For simplicity, only one contact KT and KV is shown.

Styringen St disposes of three, already described, outputs LMV, LFdb and LFub. The output LMV is across a resistor 64, connected to the base of a transistor TMV. The emitter of this transistor TMV leads to conductor L60, and the collector across a coil of a door latch magnet MV to conductor L61. The output LFdb is across a resistor 65 connected to the base of a transistor TSd. Its emitter leads over an auxiliary contact KSul in the movement direction relay Su to conductor L60, and its collector over a relay coil Sd to conductor L63.

The output LFub is across a resistor 66 connected to the base of a transistor

TSu, whose emitter via an auxiliary contact KSdl is connected to the conductor L60, and whose collector via a relay coil Su is connected to the conductor L63. The conductor L63 is also over the coil in the brake magnet MB and over the parallel-connected auxiliary contacts KSd2 and KSu2 on the relays Sd and Su connected to the conductor L60.

The main part of the aforementioned "neither-or" element consists, as shown in fig. 5, advantageously of a transistor T2. The inputs are across a number of resistors depending on the control, e.g. resistors Wl, W2, W3 and W4, connected to the base of the transistor T2. The emitter of this transistor T2 is connected to ground, while the collector across a resistor WC leads to the negative supply line L61 of the controller. Also, the collector leads to the output 70 of the "neither-or" element.

However, the input resistance W for the "neither-or" element can also be replaced with diodes, since these operate on the basis of an additional resistance.

The signal elements PS mentioned in the description are designed as shown in fig. 6. The input is added across a resistor WS

base for a transistor Tl. Its emitter

is to earth, while its collector above a signal lamp S leads to the negative supply line L61. The collector is connected to the output 71. A resistor WJ is connected to the signal lamp S to prevent a disturbance of the output power when the signal lamp S goes out.

The function of the step switch will now be described in connection with a movement example. According to the foregoing, the compartment 20 is at the stop 11 in a rest position. It appears from the description that the conductor LJS (fig. 2) carries a signal 0, and then the conductor L30 carries a signal 1. Therefore, all outputs for the elements Za and Zb (fig. 2a) are equal to 0. Since the compartment as the last movement has carried out a downward movement to the stop 11, the elements Zc have an output 1 and the elements Zd an output 0. This results in the element Pell having an output 1, while the other elements Pe have an output 0. The signal element PS11 thereby has an input 1 , which causes the corresponding position lamp to start lighting up.

In the aforementioned resting position of the compartment 20, the elements shown in fig. 2

the following output states: 30 = 1; 34 = 0; 35 = 1; 36 = 1; 37 = 0; 38 = 1; 39 = 0; 40 = 0; 41 = 0; 42 = 1; 45 = 0; 46 = 1; 43 = 0 and 44 = 0.

It is assumed that the call button Dal5 is pressed (fig. 3). The signal 1 from the push button DA15 brings the outputs of the following elements into the states: Sal5 = 0; Sbl5 = 1; File5 = 1; Fk = 0; 54 = 1; Fua = 0 and Fub = 1. Thereby the direction "up" is predetermined. The output signal 1 from the element 54 (Fig. 3a) also causes the output state 52 — 0; 53 = 1, whereby a control current flows through the emitter and base of the transistor TMV (fig. 4) which makes the emitter-collector circuit selective and activates the locking magnet MV. The direction signal LFub causes a control current in the transistor TSu. When the locking magnet MV is attracted, the contact KV closes, the relay Su energizes, and the compartment moves upwards. • At the same time, the direction signal LFub (fig. 2) of the value 1 causes the following new output states: 35 = 0; 34 = 1; 41 = 1; 42 = 0; 38 = 0 and 39 1. Thereby 46 = 0 and 45 = 1, so that conductor L46 shows a signal 0, and conductor L45 a signal 1.

During the upward movement of the compartment, the induction switch JS (fig. 1) comes out of the influence of the tab Fil, so that the conductor LJS (fig. 2) is fed with a signal 1. This gives the following new output states: 39 = 0 and 30 = 0. The conductors (fig. 2a) L30, L46 and L35 have a signal equal to 0, and the conductors L45 and L34 equal to 1. These conditions cause all inputs of the element Zall = 0, while all other elements Za and Zb have at least one input with the value 1. This causes the following new output states: Zall = 1; Zcll = 0; Zdll = 1; Pell = 0; 40 = 1; 41 = 0; 38 = 1; Pel2 = 1 and 36 = 0. When the element Pel2 has received the output 1, the tap changer is in position 1 12. As soon as the induction switch JS reaches tab F12, the signal on the conductor LJS changes from 1 to 0. This causes the following new output states: 42 = 1 ; 45 = 0; 46 = 1 and 30 = 1. Accordingly, the output of Zall = 0.

If the compartment continues to move, the induction switch JS changes from tab F12 or F13 or F14 in an analogous way the output state of the element Zal2 resp. Zal3 or Zal4, which causes a state change of the element Pel3 resp. Pel4 or Pel5.

As soon as the positioning element Pel5 shows an output signal 1, the element Sbl5 (fig. 3) gets an output 0, and the element Sal5 an output 1. At the same time, the output of Zdl4 becomes equal to 1, and the following new output states are formed: Fil5 = 0; Fk == 1 and 54 = 0. Despite this, the elevator continues its upward movement as the upward movement command remains stored in the memory element MFU (Fig. 3a).

As soon as the sliding path 26 has activated the limit switch ESu, a signal 0 occurs on the conductor LESu (Fig. 2). This results in an output 1 for the element 44, and thus for each of the elements 45 and 46 an output 0. This results in all inputs for elements Za (fig. 2a) become equal to 0, which transfers all zone units Z to the initial position for the downward movement, if this has not already happened through the normal control sequence.

As soon as the induction switch JS reaches the tab F15, the signal on the conductor LJS (Fig. 3a) becomes equal to 0. As the output signal of the element 54 just before became 0, the following new output states occur: 52 = 1 and 53 = 0, which causes the locking magnet to fall out. In addition, Fub = 0 and Fua = 1, so that the control signal for the transistor TSu is interrupted and the relay Su drops out. The auxiliary contact KSu2 opens and brings the brake B into operation.

When the target stop has been reached, the output of element 44 (Fig. 2) is equal to 0. In this position of the compartment, the output values of the elements of the tap-changer limiter SB are as follows: 40 = 0; 41 = 1; 42 = 0; 36 = 1; 37 = 0; 38 = 0; 39 = 1; 46 = 0 and 45 = 1.

It is now assumed that a passenger gets into the compartment at stop 15 and presses the push button DC11. The signal 1 that comes from the push button DC (fig. 3) causes the following new output states: Sali = 0; Etc = 1; Fgll = 1; Fh = 0; 51 = 1; Fda = 0 and Fdb = 1. Thereby the direction of movement "down" is predetermined. The output signal 1 from the element 51 (Fig. 3a) further causes output states 52 = 0 and 53 = 1, whereby the transistor TMV (Fig. 4) becomes conductive and activates the locking magnet MV. The movement signal in the conductor LFdb causes a control current in the transistor TSd. When the locking magnet MV is attracted, the contact KV closes, the relay Sd energizes and the compartment moves downwards.

At the same time, the movement direction signal on the conductor LFdb (fig. 2) causes the following new output values: 34 = 0; 35 = 1; 41 = 0; 38 = 1; 39 = 0; 42 = 1; 45 = 0 and 46 = 1, so that conductor L46 exhibits a signal 1 and conductor L45 exhibits a signal 0.

During the downward movement of the compartment, the induction switch JS comes out of the influence of the tab F15, so that the conductor LJS is supplied with a signal 1. This gives the following new output states: 42 = 0 and 30 — 0. Conductors L30, L45 and L34 (fig. 2a) has a signal equal to 0 and the conductors L46 and L35 a signal equal to 1. These states result in all inputs of the element Zbl4 being equal to 0, while all other elements Za and Zb have at least one input with the value 1. This causes the following output states: Zbl4 = 1; Zdl4 = 0; Zcl4 = 1; Pel5 = 0; 40 = 1; Pel4 = 1; 36 = 0; 37 = 1 and 38 = 0. As the element Pel4 has received the output 1, the tap changer is in position 14.

As soon as the induction switch reaches tab F14, the signal on conductor LJS (fig. 2) changes from 1 to 0. This causes the following new output states: 39 = 1; 46 = 0; 45 = 1 and 30 = 1. Thereby, Zbl4 = 0 (fig. 2a).

If the compartment continues to move, the induction switch JS changes from tab F14 or F13 or F12 the output state of the element Zbl3 resp. Zbl2 or Zbll, which results in a state change of the element Pel3 resp. Pel2 or Pell.

As soon as the position element Pell reaches an output signal of 1, the element Sbll (fig. 3) changes its output to 0 and the element Sali to 1. At the same time, the output from Zcll = 1, and the following new output states occur: Fgll = 0; Fh = 1; 51 = 0. Despite this, the elevator continues its downward movement as the downward movement order is stored in the memory element MFd (Fig. 3a).

As soon as the sliding path 26 has activated the limit switch ESd, a signal 0 occurs on the conductor LESd (Fig. 2). This causes for element 43 an output 1, and thereby for elements 45 and 46 an output 0. This results in all inputs for the elements Zb (fig. 2a) becomes equal to 0, which transfers all zone units to the starting position for the upward movement, if this has not already happened in the normal control sequence.

As soon as the induction switch JS reaches the tab Fil, the signal on the conductor LJS (fig. 3a) becomes equal to 0. As the output signal from the element 51 just before became 0, the following new output states occur: 52 = 1 and 53 = 0, which brings the locking magnet MV (fig. .4) to fall out. Furthermore, Fdb = 0 and Fda = 1, so that the control signal for the transistor TSd is interrupted, and the relay Sd drops out. The auxiliary contact KSd2 opens and brings the brake B into operation.

When the target stop is reached, the output from element 43 (Fig. 2) becomes equal to 0. In this position of the compartment, the output values of the elements of the tap-changer limiter SB are as follows: 36 = 1; 37 = 0; 38 = 1;

39 = 0; 40 = 0; 41 = 0; 42 1; 45 0

and 46 = 1.

In the example described, a tap-changer provided with two opposite directions of movement was used, i.e. that the tap-changer moves with the help of signals step by step in one or the other predetermined direction. For other purposes, e.g. for recording the frequency of use for lifts, it may be necessary to have a step switch which only moves step by step in one direction of movement, and which can be periodically returned to its initial position as required. An example of such a tap-changer is shown in fig. 7 and 7a.

For the sake of simplicity, the connection of the elements shown in these figures is described only insofar as it differs from the connection of the analogous elements shown in fig. 2 and 2a. However, to prevent confusion, the analogue elements are provided with an additional index number 1.

When the tap-changer shown in fig. 7 only connect sequentially in one direction of movement, each memory element M of zone units Zlll—Z114 is only connected to one element, namely the element Za, which element for the same reason disposes of a reduced number of inputs by one. In order to be able to bring the tap-changer into the initial position, elements Zd are supplied with a reset signal 1 via a conductor LR. This signal can, depending on the application of the tap-changer, be effected, e.g. periodically from a switch clock or from the end position. For the same reason, the tap-changer limiter SB1 is missing in fig. 7 the elements 36, 37 and 38 in fig. 2, and the elements 141 no longer exhibit the direction-dependent input. Moreover, the first input for the element 139 is connected to the output of the element 140. Instead of the correction device which acts on the memory element MSB, the element 146 in the memory element MSB1 has an input which is connected to the conductor LR.

If this step switch is used, for example, as a counting device, the following switching functions are obtained. The outputs from the elements in the initial position are: 130 = 1, and thus Za = 0; Z c = 1; Zd = 0; Pelli = 1; 140 = 0; 141 = 1; 142 = 0; 139 = 1; 146 = 0;

145 = 1; Pell2—Pell5 = 0.

A signal such as coming from a signal generator for the brake in an elevator above the conductor LJS1, causes the following new output states: 139 = 0; Zall = 1; Zclll = 0;

Zdlll = 1; Pelli = 0; 140 = 1; 141 = 0

and Pell2 = 1. As soon as the signal on conductor LJS1 disappears, the following new output states occur: 142 = 1; 145 = 0; 146 = 1 and 130 = 1. With each signal, step switches

the coupler in an analogous way one step further. As soon as a signal appears on the conductor LR

nal 1, the tap changer is brought to the output mode

ling. The conductors LP111—LP115 can be cop-

led to a print-printer not shown, which registers the position of the tap-changer at time intervals.

In order to prevent unwanted usage frequency-

points in a lift system, can e.g. one of the conductors LZ is supplied with a peak frequency device, which prevents the lift per the time-

het exceeds more than a desired peak frequency.

The object of the invention can also be implemented using other static elements, e.g. "and", "or", "not" and memory elements.

Claims (15)

1. Step switches which are assigned to a track length or section which is divided into zones and contains static switching elements and on which signals act in a signal series, which signals are brought by signal generators, and which tap-changer is particularly intended for lifts, characterized in that each zone is assigned a zone unit (Z) consisting of a memory element (M) comprising two static elements (Zc, Zd) and two pre-connected static elements (Za, Zb), which memory element is designed to store and emit signals, whereby one static element (Zc) in the memory element is affected by the output signal from one upstream static element (Za) and the other static element (Zd) in the memory element is affected by the output signal from the second pre-connected static element (Zb) or from a reset transmitter (LR) to return the tap-changer to its initial state, while a first input (L30) of one or both pre-connected elements is affected by the signal from the signal generator (JS) which produces the signal train, another input (L45 and L46 respectively) is influenced by a tap-changer limiter (SB) and a third input is influenced by one of the outputs of the respectively, the subsequent zone unit's memory element (M), whereby a further input (L34, L35) is arranged at each of the two upstream static elements (Za, Zb) which acts on these elements and determines the direction of movement of the tap changer, and that the outputs from the two static elements (Zc, Zd) in the memory element (M) on the one hand act as mutual inputs and on the on the other hand works on static position elements (Pe). 2. Tap-changer according to claim 1, characterized in that the corresponding outputs (Zc, Zd) of neighboring zone units (Z) which affect each other act on a static element (Pe) whose output indicates the position of the tap-changer. 3. Tap-changer according to claim 1, characterized in that a tap-changer limiter (SB) which is affected by the signal from the signal generator (JS), by the position elements (Pe) and by the direction of movement, affects the zone units (Z) in such a way that the tap-changer with a signal from the signal generator (JS ) only moves one step. 4. Tap-changer according to claim 1, characterized in that a tap-changer limiter (SBI) which is affected by the signal from the signal generator (JS) and by the position elements (Pe) affects the zone units (Z) in such a way that the tap-changer with a signal from the signal generator (JS) only moves one step. 5. Tap-changer according to claims 1 and 4, characterized in that the inputs (L34, L35) which determine the direction of movement of the tap-changer are connected to the outputs of an element (MF) which stores the direction of movement signal. 6. Stage couplers according to claims 1 and 3, characterized in that the outputs from the position elements (Pe) with different zone numbers act on an element (40), whose output leads to an element (41) which is affected by the one stored movement direction, and the position elements (Pe ) with the same zone number acts on an element (36), the output of which leads to an element (37) which is affected by the other stored movement direction, whereby the outputs of these elements (37, 41) on the one hand act on an element (42) which is affected by the signal from the signal generator (JS), which element's output affects one element (45) of a memory element (MSB) and on the other hand affects an element (38), the output of which is connected to an element (39) which is affected of the signal from the signal generator (JS), whereby the output of the latter element (39) leads to the second element (46) in the memory element (MSB) and the output of the two elements (45, 46) serve as mutual inputs, and whereby the output signals from the two elements ( 45, 46) affect the zone units (Zll to Z14). 7. Step couplers according to claims 1 and 4, characterized in that the outputs from the position elements (Pe) with different zone numbers act on an element (140), whose output on one side leads to an element (141), and the output of this element is connected to an element (142) which is affected by the signal from the signal generator (JS), and the output of this latter element (142) acts on one element (145) in a memory element (MSB1), and on the other hand leads to an element (139) which is influenced by the signal generator (JS), the output of the latter element (139) acting on the second element (146) in the memory element (MSB1), whereby the outputs of the two elements (145, 146) serve as mutual inputs and the output signals from the two elements (145, 146) affect the zone units (Zlll to Z114). 8. Tap-changer according to claims 1 and 3, characterized in that the movement direction signals determined by the elevator control act on a memory element (MF) in such a way that only one change of direction of movement changes the output signals acting on the tap-changer limiter (SB) and the zone units (Z) from the memory element (MF). 9. Stage coupler according to claims 1 and 3, characterized in that it comprises a rectification device (43, 44) dependent on the direction of movement, whose output signals act on the zone units (Z) in such a way that they move to the starting position corresponding to the direction of movement. 10. Tap-changer according to claims 1 and 3, characterized in that it comprises a device (43, 44) dependent on the direction of movement whose output signals act on the tap-changer limiter (SB) in such a way that its limiting effect on the zone units (Z) is cancelled. 11. Step couplers according to claims 1 and 2, characterized in that the output of the position element (Pe) acts on a signal element (PS). 12. Stage couplers according to claims 1 to 11, characterized in that the static element consists of a transistor, the emitter of which is connected to ground, the collector of which is connected to a negative supply voltage across a resistor and whose inputs via resistors are connected to the base. , 13. Step couplers according to claims 1 and 12, characterized in that the base resistors are replaced by diodes and a series-connected resistor. 14. Step couplers according to claims 1 and 11, characterized in that the collector of the transistor is connected to the negative feed line via a signal lamp. 15. Step couplers according to claims 1, 11 and 14, characterized in that a resistor is connected in parallel with the signal lamp. Publications cited: U.S. patent no. 2,085,135.