SU1246170A1 - Shift indicator - Google Patents

Abstract

This invention relates to signaling devices. The purpose of the invention is to increase reliability, resource and stability during supply voltage fluctuations. The detector contains two control windings 10, 11, one or several main magnetic-controlled contacts (OMC) and two additional magnetic-controlled contacts (DMC). The control windings 10, 11 cover all OMC and MQD. To create a current in the DMK, there are capacitors 3, 4 and a resistor 5. The signaling device is connected to the power source 1 through the switch 2. When moving the permanent magnet 6 in one direction or another, there is a vector summation of the magnetic fluxes of the constant magnet 6 and control windings 10, 11. Summation of the indicated flows allows reliable switching of the OMC. 2 Il. ND 4 05 FIG. 1

Description

The selection relates to automation, in particular to alarm devices based on contact switching by the magnetic flux of a moving permanent magnet.

The purpose of the invention is to increase the reliability of operation, resource and stability during supply voltage fluctuations.

FIG. 1 shows a circuit diagram of a motion detector; in fig. 2 - graphs of the control magnetic fluxes.

The device is powered from the power source 1 when the switch 2 is closed. The signaling device contains capacitors 3 and 4, resistor 5, permanent magnet 6, magnetic contacts 7-9, enclosed in control windings 10 and I (the initial windings are marked with a dot ). Magnetically controlled contacts (MK) 7 and 8 are switching and have respectively movable contact parts 12 and 13, fixed closing contact parts 14 and 15 and fixed disconnecting contact parts 16 and 17. MK 9 is a signal one and is intended for switching The output circuits of the detector with a certain change in the position of the permanent magnet 6 (the output circuits of the device are not shown). The detector may have one or more signal MK 9 in the form of a switching or make contact.

In the graphs (Fig. 2), the x-axis of the magnet 6 from the initial position Xn to the final position Xk is plotted along the abscissa axis. In this case, the following conventions are introduced: Xc, Ho are the points of response and release of the alarm device, respectively; PK-magnetic flux of the permanent magnet 6, measured in the zone of the location of the MC, remote from the magnet to the distance X; FS, Fo are the magnetic fluxes excited by the flow of current in the windings 10 and 11, respectively, and measured in the same zone as the magnetic flux Fm, at a certain speed of movement of the permanent magnet 6; Fu is the total control magnetic flux at point X.

The plots serve only for clarification and reflect mainly the qualitative character of the operation of the detector.

The principle of operation of the device is as follows.

In the initial position, the permanent magnet b is removed from MK 7-9, and the magnetic flux Fu is not sufficient to operate the MK. When the switch 2 is closed, the capacitor 3 is charged along the circuit 1-2-3-12-16-5-1. In this case, the resistor 5 limits the charge current. The capacitor 4 is in the initial position of the institute is discharged and is closed to the winding 11 along the circuit 4-13-17-11-4. When the magnet 6 is moved towards the MK at point X, the MK 7 switches, which relative to MK 8 and 9 has an offset of the transverse axis of symmetry towards the initial position of the permanent magnet 6. As a result, contact parts 12 and 16 are closed and contact parts 12 and 14, and the capacitor 3 is discharged to the winding 10 through a circuit 3-12-14-10-3.

When the discharge current of the capacitor 3 flows through the winding 10, the magnetic flux Fs is excited, directed according to the flux FM of the permanent magnet 6, which is ensured by polarity of the connection of the winding pins 10. The total magnetic flux Phu Fm + is maximum significantly exceeds the magnetic flux of operation of the MK 7-9. As a result, at the point Xc, a jump-like increasing magnetic flux acts on all the MCs, which leads even at a very low speed of movement of the magnet 6 to reliable switching of the MC 7-9. In this case, the capacitor 4 is disconnected from the winding 11 and is connected through a 1-2-4-13-15-5-1 circuit through closed contact parts 13 and 15. As the capacitor 3 is discharged, the current in the winding 10 and the magnetic flux Fs fall to zero. However, all MiK 7-9 remain in the state of operation due to the magnetic flux of an FM permanent magnet 6. This mode is provided by appropriate adjustment of the relative position of the MK 7-9, i.e. the offset M, K 7 relative to MK 8 and 9 should insufficient to operate MK 7 until MK 8 and 9 operate while moving the magnet 6 and to be within holding MK 7-9 in the activated state at point Xc after the end of the magnetic flux pulse FS only due to the magnetic flux of the magnet 6.

Upon further movement of the magnet 6 at any speed on the site Xc-Hk, the detector is in the triggered state, which is signaled by signal. MK 9. When the magnet 6 is reversed, the MK 8 is released to the initial position at the Ho point, the contact parts 13 are opened and 15, and the contact parts 13 and 17 are closed, which leads to the discharge of the capacitor 4 to the winding 11 along the circuit 4-i3 -17-1 -4. When the discharge current of the capacitor 4 flows through the winding 11, the magnetic flux F0 is excited, directed oppositely to the flux of the FM of the permanent magnet 6. As a result, at the initial moment of discharge of the capacitor 4, the control magnetic flux Fu F ″ -F decreases sharply to the minimum smaller than the magnetic flux release MK 7 --9. Thus, at Ho, all the MK is acted upon by a jump-likely decreasing magnetic flux, which even at very low speeds of movement

Magnet 6 leads to reliable release of all MK 7-9. In this case, the capacitor 3 switches to charge and the circuit returns to the initial state.

The motion detector provides advantages in terms of reliability, resource and stability when the supply voltage fluctuates, as it shows an abrupt change in the control magnetic flux at the points of operation and release, which increases the reliability especially at low speeds of movement of the magnet and stabilizes the characteristics at fluctuations supply voltage and dispersion of the parameters of the used magnetically controlled contacts, short-term connection of the control windings only for the time of the discharge current pulse capacitor, which increases the life of the device and reduces energy consumption. In addition, the demagnetizing effect of the magnetic flux of the control winding on the permanent magnet and the corresponding stabilization of the characteristics of the detector show up, since the magnetic fluxes of the first and second control windings are directed oppositely and how permanent the magnet is magnetised when triggered, demagnetizes when the alarm is released.

Claims (1)

Invention Formula A motion detector comprising a permanently mounted movable magnet and a first control winding, in a magnetic field of which there are at least one main magnetically controlled contact, the first additional magnetically controlled contact and terminals for connecting the power supply, the main magnetically controlled contact is intended to be included in the signal circuit, the first additional magnetically controlled contact is connected to one of the terminals of the first control circuit. 0 five 0 five 0 Q five the coil, and its transverse axis of symmetry is displaced in space relative to the transverse axis of symmetry of the main magnetically controlled contact towards the initial position of the permanent magnet, characterized in that, in order to increase reliability, service life and stability during supply voltage fluctuations It is equipped with two capacitors, a current-limiting resistor, the second additional magnetic contact of the second control winding, and the additional magnetic contacts are used as additional magnetic contacts. The closing magnetically controlled contacts, both control vol. the coils cover all magnetic contacts, the second additional magnetic contact is located so that its transverse axis of symmetry coincides with the transverse axis of symmetry of the main magnetic contact, the beginning of the first control winding is connected to the end of the second control winding and one of the plates of each of the capacitor, the other plates of each of which are connected to the moving contact details of the additional, separate, magnetically controlled contacts, the beginning of the second control winding is connected to one of the The movable contact parts of the second additional magnetic ferrule contact, the specified connection of the first additional magnetic contact and one of the terminals of the first control winding between them is made by one of the fixed contact parts of the magnetic contact, and the end of this control winding, others fixed contact details of additional magnetic control contacts are interconnected and with one of the terminals of the current-clamping resistor, the other output of which is connected to one of the power supply terminals, and the other power supply terminal is connected to the start of the first control winding. Fm Days 0 ai VNIIPI Order 4008/46 Circulation 643 Signature-, Branch PPP "Patent -, Uh-; city. Design.