SU739669A1 - Method and apparatus for bounce-free control of switching devices - Google Patents

Description

The invention relates to a bounce-free control of switching devices containing magnetically controlled sealed contacts (rkony or gesakon) and control winding, and describes a control method, as well as a device for implementing this method.  Hermetically magnetically controlled contacts, in particular, those that retain their reed switches, are called Gezaco. They are widely used in quasi-electronic automatic telephone stations (CE PBX).  For one PBX AE number, on average, it requires about 40 Geza-law.  A known method of controlling gezacons (reed switches) in relays and matrix connectors (MS), characterized in that they form a control signal and feed it to the corresponding control windings of the gezacon (reed switch) selected by distribution unit 1.  However, contact parts chattering during the closure reduces the technical resource and reliability of any type of contact.  A large number of short-term closures and openings of contact parts occur, especially in circuits with an electrical load, which leads to the formation of an electric arc, as a result of which the contacts quickly go out of order.  In order to close and create the required pressure contact, which provides the necessary electrical conductivity in the contact zone, the contact parts are open, they are usually magnetized before the magnetic induction of their material saturation.  In this case, the movement of the contact parts occurs under the action of the maximum possible force of the magnetic interaction, which significantly increases as the magnitude of the contact gap decreases.  Therefore, the contact parts in the process of acquiring at the time of their first contact are significant speed and kinetic energy, which is the main reason for the bounce of contact parts reis aktogov.  The magnetization of kyakt-ethekse kDHOB in relays and matrix connectors (and in other similar systems) occurs under the influence of a powerful pulsed magnetic field that occurs when current passes through the control windings.    The methods of reducing (suppressing) contact bounce are based on the fact that at the moment of contact of contacting contact details, their speed should be close to zero.  In the known form of FORMIR5TOT, a different polarized control signal is applied to the control winding of the hexacon.  This produces magnetization by a pulse of contact-t-parts, which, under the action of a magnetic field caused by this pulse, begin to approach;  But the impulse of the inverse floor pH. The hind brakes converging contact parts, which reduce their speed of movement.  Then the magnetic systems of contact parts are affected by a pulse of greater amplitude, as a result of which the contacting parts approach each other and they are magnetized to a magnetic saturation induction.  Thus, the closure of contact parts occurs at a low speed of their approach, and their magnetization before the magnetic induction of saturation contributes to the fact that the contact part after the first closure /. , (collisions) remain practically in a closed state, and the chattering time is significantly improved compared to the usual control of the gezacons.  A single well-known method cannot be used to control the switching field of quasi-electronic exchanges; in the control circuits of the matrix connectors of which thyristor-type switching elements are used, since in this case the pulse b. will not be able to pass through the thyristors into the control windings of the heaters; It is not possible to use CE PBXs to control the switching field in horizontals or verticals of the matrix connectors of which interconnect diodes are included.  In this case, the pulse cannot be run into the control windings of the laws.  In addition, there is a significant level of interference induced in adjacent circuits at times of start and end of control.  It is also known a control device comprising a forming unit and a distribution unit in which the forming unit contains a storage capacitor, in a charge circuit of which a series-connected choke and a diode are connected from a constant voltage source, and a series-connected controlled switching element is included in the discharge circuit. and the primary winding of the output transformer, the secondary winding of which is connected to the load I via the distribution unit.  However, the shape of the pulses produced by & so by such a device does not reduce the level of interference induced by the control signal in adjacent circuits.  The purpose of the invention is to expand the scope of application of the control method and reduce the level of interference induced by the control signal in adjacent circuits.  The goal is achieved by the fact that, in the method of controlling switching devices on gezacons, carried out by generating a control current pulse and applying it to the control winding, the control signal of a form in the form of a unipolar pulse, a current with a stretched leading front, having a flat part, the duration of which corresponds from the beginning of the movement of the contact parts of the gccon (when closed) to their contact.  The amplitude of the flat part of the impulse being formed corresponds to the magnitude of the magnetic induction necessary to start the movement of the contact parts.  The maximum amplitude of the pulse being formed is chosen in cO corresponding to the value of the saturation induction of the contact parts.  The leading edge of the impeller being formed in front of the flat part gives the shape of the leading front of the peg of the tin-shaped pulse.  A device that implements the inventive method, consisting of a forming unit and a distribution unit, in which the forming unit contains a first storage capacitor, in a charge circuit of which from a constant voltage source is connected in series; the first choke and the first diode, and the first connected controlled switching element and the winding of the output transformer, the secondary winding of which through the distribution unit is connected to the load, are connected to the discharge circuit; a second accumulator capacitor connected to the constant voltage source is connected through the distribution unit a choke and a second diode.  The circuit is the second cumulative conden. five.  .  739669 contains a serially connected second controlled KOMMjnraiiHone element and the primary winding of the second output transformer.  The second windings of both transformers 5 are connected through an uncoupling circuit You.  The inputs of the controlled switching elements are connected via a delay element.  A discharge choke with a ferromagnetic core is connected to the discharge circuit of both accumulative to capacitors in series with the primary winding of each output transformer.  On ijwr.  Fig. 1 shows the formed im- (5 tupc current supplied to the control winding & l of the switching device; fig.  Fig. 2 shows a simplified diagram of the device in which the block for forming an extract (at the {fincinial scheme; fig. 3, 20 shows timing diagrams showing the formation of a control pulse of the wiring circuit shown in Fig. 1, the proposed method is free) of controlling the switching devices 25 consists in the fact that they first form a unipolar control signal and then, through the distribution unit, feed it into co. the corresponding control windings for the operation of switching devices (Herzo con and Gezakonos 1X relays, reed and Gezakonovy matrix connectors, etc. P,).  At 8TOM, the leading edge of the pulse is formed stretched with a flat part, the duration of which corresponds to time.  Neither from the beginning of the movement of the contact parts of the gezacon to the contact with the touch.  The amplitude of the flat part of the pulse is chosen according to the magnetic induction required to start the movement of the contact parts.  The maximum pulse amplitude is chosen according to the induction saturation value of the contact-decimals, the maximum amplitude of the pulse being formed and the pulse duration Lz, is chosen from the magnetization reversal condition of the contact parts of the gezacon to saturation, and is determined by the following extract: , ":-" about. 5p-); “-Gi (°. , 2jjh Bs, moreover, j is the product, where X is the electrical conductivity of the contact details, m Ω-mm hectares are on the other hand, where 55 is where the thickness of the contact details ,.  m; In, - mapgatna induction satura, chi.  T; ,  --VnpH4eMt. o-. 43t contact form permeability; P And and W - the number of turns of the control winding; Kutz - the impermeability coefficient of the magnetic field of the control winding, BO is the average length of the magnetic field line. 1 control winding, m, H coercive vortex of contact-part material, A / m.  and 4mg.  Figure 1 shows that the current in the coil winding increases from 0 to 3p up to the time T, which corresponds to the motion of the contact parts of the GezacoV this time, the magnetic force of them is equal to the elastic force of the counterstrike.  Then the contacting surface-parts come closer during the period tp and at the moment I touch each other.  The duration tp of the flat part of the bottom front of the pulse and its amplitude is determined by (T, based on the condition that the ment t is the speed of their movement is equal to (or has a small value.  Thus, the duration of the flat part of the tp pulse and its amplitude are respectively:.  VJ U PI) W po (-) th а - magnetic induction of open KpirraKT parts, T; - the amount of contact overlap.   details, m; Kp is the coefficient of scattering of the magnetic flux in the contact gap ;.  .  Ogs-cojMJVP g m c (C-AF / cfo C-C1;) tlCEd h о гг () contact intervals, о, respectively, the initial and attainable inflow Зр, m; given mass contact details, kg; 773 Е - modulus of elasticity of the 1st kind of contact details N / m; : 61 — pin diameter of contact details, Mi At time point 1, when the contact-parts of the gezacon are in contact, a further increase in current begins to a value of 3 g, at which the material of the contact-parts is magnetized to saturation.  Since from the moment of 1/2 the force of the thread begins to dominate more and more over the elastic force of the material of the contact parts, after the first contact they remain almost in the closed state t. e.  Provides minimal bounce or none.  Impulse (see  FIG.  1) the control has a rather complicated form.  However, it is realized by relatively simple means. For this, it is sufficient to impose on each other two symmetric bell-shaped pulses taken from. phase shift (see  FIG.  3).  In this case, the amplitude of the pulse is chosen equal to the calculated value of Dp.  The amplitude of the second pulse is taken to be equal to the magnitude of Ep.  The duration of the leading edge of the first bell-shaped pulse is equal to φ of the calculated pulse (Fig. 1).  The delay time of the second bell-shaped pulse relative to the first is chosen to be approximately equal to the calculated value.  In this case, it turns out that the leading edge 1f of the control pulse of FIG. 1 is nridane, the shape of a bell-shaped pulse.  This ensures a significant reduction of interference levels, which are impacted by this pulse in adjacent circuits.  A device that implements the method contains (see  FIG.  2) the forming unit 1 and the distribution unit 2, through which the current pulses are distributed to the corresponding control windings of the switching devices 3.  forming unit 1 is made as follows.  The inductor 5 and the first diode 6 are connected in series to the charging circuit of the first heating capacitor 4 from the constant voltage source E and the discharge circuit is connected to the distribution output 2 of the first output transformer 7, which is connected to the distribution unit 2 via a diode 8. , the first forming choke 9 with a ferromagnetic core and the first controlled switching element 10.  In the discharge circuit of the second cumulative capacitor 11 of the field 8.  A second diode 12 is connected with the choke 5, and a second forming choke 13c fern is connected in series to the discharge circuit of this capacitor 11.  by the magnetic core, the primary winding of the second output transformer 14, the secondary winding of which through diode 15 is connected to distribution unit 2 in parallel with the secondary circuit of the output transformer 7, and the second controlled switching element 16.  Between the inputs of the controlled switching elements 10 and 16 there is included a 17-delay element triggered by a signal arriving at its input 18.  The device works as follows.  In the initial state, both storage capacitors 4 and 11 are charged before a voltage, for example, equal to the voltage of the power source E.  In principle, the voltage on the storage capacitors M (it exceeds the voltage of the power source.  At the moment of time to when it is necessary to apply a current pulse to the control windings of switching devices 3, a signal is applied to input 18 of delay element 17.  its launch.  The element is triggered on the controlled switching element thyristor 16.  The storage capacitor I is discharged through successively connected forming choke 13, the primary winding of the output transformer 14 and the connected thyristor 16.  Go the secondary winding of the output transformer 14 through the diode 15 to the input of distribution unit 2 (see  FIG.  2) a pulse of current of a bell shape is received (see  FIG.  3 a).  The current pulse is bell-shaped due to the presence in the circuit of the discharge of the storage capacitor 4 and the forming throttle 13 with a ferromagnetic core.  The switching on of the thyristor 16 can also be carried out simultaneously with the launching of the delay element 17 with the aid of a signal arriving at the input 18 of the element 17, or with an additional signal.  At time i (see  FIG.  36) the delay element 17 generates a signal to turn on the thyristor 10.  The thyristor 10 is turned on and the storage capacitor 4 is discharged through successively connected forming choke 9, the primary winding of the output transformer 7 and the switched on thyristor 10.  . From the secondary winding of the output Transformer 7 through the diode 8 to the input of the distribution unit 2 receives a second impulse of a bell-shaped current (see  Fig, 36).  As can be seen from FIG.  3 a and b, two current pulses are supplied to the input of distribution unit 2 and, therefore, two control current windings are switched, shifted each other by a delay time and the form of the resulting current pulse in the control windings will be the same as in FIG.  3 in.  The duration of the extended part P of the leading edge of the pulse (see  FIG.  Per) can be adjusted by changing the time i (see  FIG.  36), which is performed by delay element 17.  Thus, the proposed method for controlling the operation of switching devices, as compared with the known, expands the scope of application, due to the fact that it is suitable for controlling a switching field of a short circuit telephone exchange, in which the decoupling diodes are turned on in the horizontal lines and the vertical connectors; suitable for controlling the switching field of quasi-electronic exchanges, in the control circuits of the matrix connectors of which switching elements are used, while providing a small level of interference induced in adjacent circuits in the process of controlling the switching zero of quasi-electronic exchanges.  This is due to the fact that the leading edge of a current pulse in front of the flat part gives the shape of the leading edge of a bell-shaped pulse.  The implementation of the proposed device that implements the described method does not cause any technical difficulties. Its scheme is simple and reliable in operation.  , . . ; , Claim 1, A method without / rebate control of switching devices, containing reed switches and an impingement winding performed by generating a control signal and feeding it into said winding is distinguished by the fact that, in order to expand the field of application of the method, the control signal is formed in the form of a unipolar current pulse with an extended leading front, having a flat part / duration of which corresponds to the time from the beginning of the movement of the contact t-part of the reed switch to their contact, and the amplitude to the magnitude of the magnetic induction required to start the movement of contact parts, with the maximum pulse amplitude of 7 6910 chosen in accordance with the magnitude of the induction saturation of the contact details.  2 The method according to claim.  1, characterized in that, in order to reduce the level of interference induced in adjacent chains, the leading edge of said control pulse in front of the flat part gives the shape of the leading edge of a bell-shaped pulse.  3 An apparatus for carrying out the method of claim.  1, containing serially connected. a distribution unit and a forming unit, including a storage capacitor, in a charge circuit of which a series-connected choke and a diode are connected from a DC source, and a discharge circuit includes a series-connected controlled switching element and the primary winding of the output transformer, the secondary winding of which is connected to a load through a distribution unit, which differs from the fact that a different storage capacitor, another diode, another controlled switching element are introduced into the device nt, another output transformer, decoupling elements and a delay element indicated by another storage capacitor are connected to a terminal for connecting a source of constant voltage through the specified choke and the indicated other diode, and the discharge circuit of another positive capacitor switching element and the primary winding of the specified other output transformer, the secondary windings of both transformer terminals are connected through specified isolating elements, and the inputs of both controlled switching elements are connected through a specified delay element.  four. The device according to claim.  3, that is, with the introduction of two forming throttles with a ferromagnetic core, each of which is connected to the discharge circuit of one of the storage capacitors in series with the primary winding of the corresponding output transformer. .  Sources of information taken into account in the examination.  one.  USSR Author's Certificate No. 385404, H 04 M-9/06, 1971.  2  Lutov M.  F.  Quasi-electronic vehicle.  Collection of Communication Techniques Abroad, M. , Holy Hearts, 1968, p.  102-1ООЗ, is.  9.8 and 9. 9.

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Claims (4)

Claim 1, The method of bounce-free control of switching devices containing reed switches and a control winding is carried out ⁴⁵ times by generating a control signal and supplying it to said winding, characterized in that, with the expansion circuit of the method scope, the control signal is formed as 50 unipolar current pulse with a stretched leading edge having a flat part, the duration of which corresponds to the time from the beginning of the movement of the reed contact by the contact to their touch, and the amplitude is the magnitude of the magnetic induction, mine to start the movement of contact parts, with the maximum amplitude of the pulse 739669 10 is selected in accordance with the magnitude of the saturation induction of the contact parts. 2. The method according to π. 1, I differ in that, in order to reduce the level of interference induced in adjacent circuits, the leading edge of the specified control pulse in front of the flat part is shaped like the leading edge of a bell-shaped pulse. 3. A device for implementing the method according to π. 1, comprising a series-connected distribution unit and a forming unit including a storage capacitor, in the charge circuit of which a diode and a diode are connected in series from a constant voltage source, and a controllable comm., Tation element and primary output winding are connected in series to the discharge circuit a transformer, the secondary winding of which is connected to a load through a distribution unit, characterized in that another storage capacitor, a different diode, are introduced into the device , another controlled switching element, another output transformer, decoupling elements and a delay element, said other storage capacitor connected to a terminal for connecting a DC voltage source through said inductor and said other diode, wherein the discharge circuit of another storage capacitor is made in the form of series-connected said other controlled the switching element and the primary winding of the specified other output transformer, the secondary windings of both tra The informants are combined through the indicated decoupling elements, and the inputs of both controlled switching elements are connected through the specified delay element. 4. The device according to claim 3, which includes the fact that two forming chokes with a ferromagnetic core are introduced into it, each of which is connected to the discharge circuit of one of the storage capacitors in series with the primary winding of the corresponding output transformer.