SU830594A1 - Sealed contact - Google Patents

Description

(54) Reed

one

The invention relates to electrical engineering and can be used in the design of switching automation elements.

Sealed contacts (reed switches) are known, for example, of membrane type, containing a hermetic housing, inside of which there are ferromagnetic contacts, which can be made in the form of a hollow core and a membrane. Depending on the technical requirements, the shape of the membrane can be changed, in particular, the membrane can have an opening in the central part 1.

However, an increase in the switching power of such reed switches is accompanied, firstly, by an increase in mass, i.e., the inertia of the moving contacts to achieve the permissible density of the current of the switched electric circuit passing through them, secondly, by increasing the gap between the contacting contact areas to reduce their electric erosion, therefore, such reed switches cannot provide sufficient speed. At the same time, the presence of electrical erosion, one of the forms of which is the splashing of material in contact with areas

contacts at the time of arcing between them, delays the process of switching off the electrical circuit by a reed switch and reduces its reliability. In addition, additional sources of electrical energy are required to provide indication of the state of reed switches.

A reed switch is also known, containing a cylinder divided into two sealed cavities, two contact cores installed in the cylinder and having conclusions from one of its ends, and two electrodes, each of which is located at the same distance from the contact cores, where the cylinder cavity located closer to the terminals of the contact cores, filled with inert gas 2.

Claims (5)

In the specified reed switch, during the ionization of the gas, when the contact cores are open, an electric current of the switched circuit flows through the gas discharge gap. In this case, the voltage drops across the gas discharge gap, therefore the current in the switched circuit only reaches the nominal value of a ps of reliable contact closure of the contact serdes. The change in the switching current% in I MOHTi.i is closed, and the un-unlocking of the contact .. G) LS1P1K () is caused by the occurrence of a noNi; i i; x processes in a switched circuit, there seems to be a danger of the occurrence of a loooooooooooooooobing between contiguous congresses of the cores. In addition, the contact resistance of the closed contacts is much thicker than the resistance of the gas discharge gap between the contact cores, through which almost all the switched current flows through the circuit, and the mass of the contact cores increases in proportion to the switched power. As a result, such a reed switch does not provide the necessary speed and reliability, 11 its scope is limited. Ce,: p invention - expansion of the scope of the reed switch. This goal is achieved by the fact that in a reed switch containing a cylinder divided into two sealed cavities, two contact cores installed in the cylinder and having conclusions from one of its ends, and two electrodes, each of which is located at the same distance from the contact cores, moreover, the cylinder cavity, located closer to the terminals of the contact cores, is filled with an inert gas, the electrodes are introduced into this cavity. Electrodes can be installed on the outside of the contact cores. Electrodes can also be installed between the contact cores. At the same time, in order to expand the functionality, the cavity located closer to the terminals of the contact cores can be divided by electrodes and contact cores into areas that are isolated from each other by melting the glass c. metal and filled with different gas: the color of the radiation. In addition, isolated from each other areas of the cavity, located closer to the terminals of the contact cores, can be filled with gas under different pressure. By placing the electrodes inside the cavity located closer to the terminals of the contact cores, it is possible to supply both the alternating and constant ionizing sources of this voltage to the electrodes to compensate for the voltage drop across the discharge gaps. Insulating parts of the cavity that are closer to the terminals of the contact cores, and filling these parts with gas with a different color of radiation when it is ionized, expands the indication capabilities of the reed switch by using gases or vapors, such as mercury, which have different radiation spectra. In particular, neon has an orange-red candle, argon is purple, and mercury vapor is blue. In addition, filling with different gas bulbs allows varying the breakdown voltage of the gas discharge gaps, which can also be achieved by varying the pressure of the gas or gases used. FIG. 1 shows the first version of the reed switch, frontal projection; in fig. 2 - the same; view from above; in fig. 3 is a structural scheme for the inclusion of a reed switch in a switched electrical circuit; in fig. 4 and 5 are equivalent electric circuits of the state of this circuit, respectively, before the closure (at the moment of opening) of the contact cores and after their closure; in fig. b - the second version of the reed switch, frontal projection; in fig. 7 - the same, top view; in fig. 8 - the third version of the reed switch, frontal projection; in fig. 9 - the same, side view; in fig. 10 - the fourth version of the reed switch, frontal projection; in fig. 11 - the same, side view; in fig. 12 is an equivalent electrical circuit including a reed switch made according to the first (Fig. 1) or second (Fig. 6) variant, from the moment of opening its contact cores to the moment of switching on the electric switching circuit. The reed switch, made in the first embodiment (Fig. 1 and 2), contains a sealed-glass container 1 having cavities 2 and 3. Cavity 2 is evacuated, and there are contact elements of ferromagnetic contact cores 4 and 5, the corresponding current leads b and 7 which pass through the cavity 3, filled with neon, where they are separated from each other by a gas discharge gap 8. In the same cavity 3, an electrode 9 is inserted, separated from the current leads by a gas discharge gap 10, and an electrode 11, separated from the current lead 7 of the gas discharge. interval 12. To currents ode 6 (. Figure 3) is connected through the load 13, the positive source terminal 14 DC to the current lead 7 - its negative terminal. The respective terminals of the controlled source 15 are connected to the electrodes 9 and 11, in series with which the ballast resistance 16 is connected. The reed switch works as follows. If the estimated turn-on time of the switched electrical circuit, consisting of the source 14 and the load 13, is less than the time required for closing and subsequent opening of the contact cores 4 and 5, then during the turn-on time, the source 15, switched on according to the source 14, is energized the electric field in the gas discharge spaces 10 and 12 is sufficient for ionization, after which the source 15 compensates for the voltage drop across the series-connected resistances 16 and for Kah 10 and 12 than is achieved through the load 13 protokanie nominal current (FIGS. 4, where the gaps 10 and 12 are designated conventionally as the arrester, and the arrow shows the direction of current). To disconnect the switched circuit, the excitation of the source 15 is stopped, the gas-discharge gaps 10 and 12 are deionized, thus achieving the disconnection of the source 14 from the load 13. If the expected turn-on time is equal to or more than the total time of closing and opening of the contact cores 4 and 5, then the source 15 is simultaneously excited, and a magnetic field is created along the axis of the balloon 1. In this case, prior to the closure of the contact cores 4 and 5, the current in the switched circuit is created in this way. After the closures of cores 4 and 5, under the action of a magnetic field, they form an adjacent branch of two circuits, one of which includes source 14 and load 13, and the other source 15, resistance 16 and intervals 10 and 12 (Fig. 5, where the arrows shows the direction of the currents in the circuits). In this case, the magnitudes of the excitation sources 14 and 15 currents do not change, the directions of which in the branch formed by contact cores 4 and 5 are opposite, i.e. the resulting value of the current switched by them is equal to the difference of currents in the circuits - zero due to their equality arcing between contiguous areas of cores 4 and 5 at the time of their closure. After reliable closure of the cores 4 and 5, the magnitude of the current excited by the source 15 is changed to the value at which the desired brightness of the light emitted by the ionized gaps 10 and 12 is reached (the current can also be reduced to zero when the radiation of the reed switch is not necessary or galvanic the connection between sources 14 and 15 is undesirable), which is accompanied by gas deionization in the intervals 10 and 12). At the moment of removal of the magnetic field, the current excited by the source 15 is again restored to the minimum value for a period of time sufficient for the occurrence between the contacting surfaces of the contact cores 4 and 5 of the gap, the breakdown voltage of which is longer than the breakdown voltage of gap 8, At the same time, there is no change in the current in the switched circuit at the time of opening of the cores 4 and 5, which ensures the absence of arcing between their contacting surfaces, after the formation of the above the gap between which the excitation of the source 15 is stopped, and the gas in the intervals 10 and 12 is deionized. In this case, if there is no inductance in the load 13, the switching process ends. If the inductance is present, then due to the arising overvoltage a breakdown of the gas discharge gap 8 occurs, and the switching process ends after the energy stored in the inductance is consumed and the gap 8 is deionized. When the polarity of the source 14 changes, the implementation of which the bipolar voltage value at its output from the moment of opening the contact cores 4 and 5 until the moment of switching on the switched circuit described above can be set ene equal to the voltage at the output of the source 14, the springs 14 and 15 are turned counter. In this case, the state of the switched and control circuits is equivalent to the state of the circuits and the circuit shown in FIG. 12. This makes it possible to reduce the magnitude of the breakdown voltage of the gaps 10 and 12 (i.e., respectively, reduce their burning voltage to reduce the power dissipated to them during switching on the switched circuit and reduce the power of the source 15). The reed switch shown in FIG. 6 and 7, contains a sealed glass cylinder having cavities 2 and 3. Cavity 2 is evacuated and the contact elements of ferromagnetic contacts of cores 4 and 5 are placed there, the corresponding current leads 6 and 7 of which pass through cavity 3, where they are separated from each other the other is spaced 8, and their side portions are hollowed into the body of the balloon 1, which achieves isolation of gap 8 from cavity 3 and dividing it into parts, in one of which an additional electrode 9 is placed, separated from the current lead by interval 10, and in the other electrode 11, separated from the current The lead-in of gap 7 is gap 12. Interval 8 is filled with argon, in part of cavity 3 with neon. The switching scheme and operation of the reed switch are similar to the first option, except that if there is overvoltage in the switched circuit, the reed switch emits a purple color due to the ionization of argon in interval 8, while the switched on state of the reed switch is characterized by orange-red neon radiation in intervals of 10 and 12. The reed switch shown in FIG. 8 and 9, contains a sealed glass cylinder 1 having cavities 2 and 3. Cavity 2 is evacuated and contains contact elements of ferromagnetic contact cores 4 and 5, the corresponding current leads 6 and 7 of which pass through a neon-filled cavity 3 where separated by a gap. Electrode 9 is also located in cavity 3, separated from current lead b by gap 10, and from current lead 7 by gap 17, and electrode 11 separated from current lead 7 by gap 12, and from current lead 6 by gap 18. Moreover, electrodes 9 and 11 are also separated spaced from each other. 8. Wiring diagram. The reed switch is shown in FIG. 3. Reed switch. works as follows. During the creation of a magnetic field along the axis of the cylinder (Figs. 8, 9 and 3), a source 15 is excited, from the output of which a voltage is applied across the resistance 16 to the electrodes 9 and 11. The potential difference between the electrode 9 and the current lead 7, as well as electrode 11 and current lead 6 decreases, since the voltage is applied to these pairs of the same sign, and the voltage of the electric field in the gaps 17, 18 decreases accordingly, which excludes their breakdown. At the same time, the potential difference between the electrode 9 and the current lead 6, as well as between the electrode 11 and the current lead 7, increases as the voltage is applied to these pairs of opposite sign, and the strength of the electric field in the gaps 10 and 12, respectively, increases to a value sufficient for their p-robo, what is achieved by a consistent inclusion of sources 14 and 15, and in on. load 13 is set to rated current. After a reliable closure of the contact cores 4 and 5 under the action of the magnetic current, excited by the source 15, is changed to the value at which the necessary intensity of light emission by the reed switch is provided. When the magnetic field is deflected by the source 15, a current equal to the rated current flowing through the load 13 is again excited for the opening time of the contact cores 4 and 5, after which the excitation of the source 15 stops, the voltage at its output decreases to zero, the gas in intervals of 10 and 12 is deionized and the switching process ends. When the polarity of the source 14 is changed, the polarity of the source a 15 is not necessary to effect their consonant inclusion, since in this case such inclusion is carried out automatically in a similar way through the discharge gaps 17 and 18. For reliable operation of such a reed switch, The voltage of each of the intervals 10, 12, 17, and 18 was the same and had a value of at least half as small as the value of the breakdown voltage of gap 8 between electrodes 9 and 11. At the same time, the maximum working time the reed switch voltage must be less than the smaller of the three values of the burning voltage of the gaps 8 between the current leads 6 and 7 or, taking into account the technological variation, less than the total value of the burning voltages of one of the pairs of gaps - 10, 12 or 17, 18, and the minimum operating voltage the reed switch should be greater than the absolute value of the difference of the total values of the breakdown voltage of the same pairs of gaps 10, 12 and 17, 18. Due to the fact that when changing the direction of the switched current, respectively, different pairs Wefts - 10, 12 or 17, 18, - the change in spatial sources may emit light visual determination of voltage current in the switched circuit. The reed switch shown in FIG. 10 and 11, contains a sealed glass cylinder 1, having cavities 2 and 3. Cavity 2 is evacuated, and the contact elements of ferromagnetic contact cores 4 and 5 are placed there, the corresponding current leads 6 and 7 of which pass through cavity 3, where the middle sections of their surface along the axis of the cylinder 1 are separated from each other along glass spans m 8, the electrode 9, separated from the current lead by a gas discharge gap 10, and the current lead 7 7, a gap 17, and the electrode 11 separated from the current lead, are also attached to the free sides of which 7 span m 12, and from the tokovod 6 - a gap 1, the electrodes 9 and 11 are located on both sides of the spa 8 symmetrically relative to each other and the current leads 6 and 7. The peripheral lateral parts of the electrodes 10 and 12 and the current leads 6 and 7 flow into the body of the balloon 1 than is achieved isolation of each other, intervals 10 and 12, filled with neon, and intervals 17 and 18, filled with argon from each other. The switching circuit and the operation of the reed switch are similar to the switching circuit and operation of the reed switch shown in FIG. 8 and 9, except that, depending on the direction of the switched current, the chromaticity of the radiation from the reed switch light changes, since the ionization of gaps 10 and 12 is accompanied by orange-red emission of neon, and the ionization of gaps 17 and 18 by violet argon radiation, which is achieved by the corresponding gas pressure. It should be noted that the cavity in which the contact elements of the ferromagnetic contact cores 4 and 5 are placed, can not only be evacuated, but also filled with protective gas and or dielectric fluid, such as transformer oil, and sections 6 and 7 of the current lead, located against the additional electrodes, can be made of both ferromagnetic and non-ferromagnetic materials, and the gaps between them can also be filled with a mixture of gases containing, for example, hydrogen. For the reed switch to work reliably, the response of the compensating source must be at least the same order as the process of ionization of the gas-discharge gaps between the additional electrodes and the corresponding sections of the current leads of the contact cores, and the ionization time of these gaps must be less than the time of ionization of the gap between the contact areas contact cores, in the case of filling the cavity in which they are placed, with gas. To reduce the power of the compensating source and reduce the dissipated power at the gas discharge gaps, one of the additional electrodes can be connected to the corresponding current lead, but in this case the separation between the switched and control circuits is worsened. The absence of arcing between the contacting areas of the contact cores allows to reduce the gap between them, which is facilitated by the high dielectric strength of the vacuum. Claims. A reed switch containing a cylinder divided into two sealed cavities, two contact cores installed in the cylinder and having conclusions from one of its ends, and two electrodes, each of which is located at the same distance J2 of the SRI from the contact cores, and the cylinder cavity is located closer to the terminals of the contact cores, filled with an inert gas, characterized in that, in order to expand the field of application, the electrodes are introduced into the cavity of the balloon, which is located closer to the terminals of the contact cores. 2. Reed switch as claimed in claim 1, wherein each electrode is installed between one of the contact cores and the wall of the balloon. 3. Reed switch according to claim 1, characterized in that the electrodes are mounted between contact cores. 4. Reed on PP. 1, 2 or 3, characterized in that, in order to extend the functionality, between the electrodes a sealing partition in the form of a glass-to-metal glass was inserted, separating the cavity of the balloon, closer to the terminals of the contact cores, into two parts, each filled gas with a different color of radiation. 5. The reed switch according to claim 1, characterized in that the parts of the cavity located closer to the terminals of the contact cores are filled with gas at different pressures. Sources of information taken into account in the examination 1. B. Bul, K., Puchkov A. S., V. Shoffa. Valve-Genestkovye and membrane sealed magnetically-controlled switching devices. M., 1973, p. 18, 19. ten 15 9 four,, ) 147 / 7 12 (rig 5 FIG. 6 S of FIG. eight eight P Fig.7 5 ten FIG. W 73 12 FIG. 11 15