RU2032955C1 - Hermetically sealed movement sensor - Google Patents

Abstract

FIELD: electrical engineering. SUBSTANCE: hermetically sealed movement sensor has hermetically sealed reed relay, two bar permanent magnets magnetized longitudinally and mounted perpendicular to longitudinal axis of hermetically sealed reed relay on one of its sides but on different sides from overlapping of contact-parts of hermetically sealed reed relay of like poles towards hermetically sealed reed relay and mobile magnetically soft part placed on other side of hermetically sealed reed relay relative to permanent magnets. EFFECT: expanded application field. 5 cl, 5 dwg

Description

 The invention relates to electrical engineering and can be used in automation, regulation and control systems to control the movement of objects.

Known reed switch displacement sensor containing a reed switch, a rod permanent magnet mounted with one of its poles to the overlapping area of the contact parts of the reed switch, and a U-shaped magnetic circuit mounted on a permanent magnet [1]
Such a motion sensor has a limited scope, since the reed switch is controlled by moving a permanent magnet along with the magnetic circuit.

The closest in technical essence to the proposed one is a reed switch of displacement, containing a reed switch, two rod permanent magnets magnetized longitudinally and mounted perpendicular to the longitudinal axis of the reed switch on one side of it, but from different sides from the overlap of the contact parts of the reed switch, and a magnetically soft part installed with the possibility of displacement [2]
The disadvantage of such a reed switch is low performance due to the large differential stroke.

 The aim of the invention is to improve performance.

 This goal is achieved by the fact that the rod permanent magnets are facing the reed switch with the same poles, and the magnetically soft part is located on the other side of the reed switch with respect to the permanent magnets with the possibility of movement along the reed switch.

 In the reed switch of the displacement magnetically soft part and permanent magnets can be located on different sides relative to the longitudinal axis of the reed switch.

 In the reed switch of the displacement magnetically soft part can be located so that it is crossed by a plane passing through the longitudinal axis of the reed switch and the perpendicular axis of magnetization of permanent magnets.

 The reed switch of displacement can be equipped with an additional reed switch mounted at opposite poles of the permanent magnets with respect to the main reed switch and parallel to the last, and the magnetically soft part is made and located so that its length in the direction of the magnetization axes of the permanent magnets is greater than the distance between the longitudinal axes of the reed switches.

 In the reed switch of displacement, switching reed switches with disconnecting contact parts located on one side of the ends of the cylinder can be selected as reed switches, these reed switches are installed in such a way that a magnetically soft part is located at the ends of the reed cylinders with closing contact parts.

 In FIG. 1 schematically shows a reed contact displacement sensor; in FIG. 2 reed switch of displacement with magnetically soft part located on the opposite side of the reed switch with respect to permanent magnets, left view; in FIG. 3 reed switch of displacement with magnetically soft part located in such a way that it is crossed by a plane passing through the longitudinal axis of the reed switch and perpendicular to the axis of magnetization of permanent magnets, left view; in FIG. 4 reed switch displacement with an additional reed switch; in FIG. 5 reed switch displacement switch.

 The reed switch displacement sensor contains a reed switch 1, two rod permanent magnets 2 and 3, magnetized longitudinally and mounted perpendicular to the longitudinal axis of the reed switch 1 on one side of it, but on different sides from the overlap of 4 contact details of the reed switch 1 and poles of the same name (for example, N towards the reed switch 1, and a movable magnetically soft part 5).

 The soft magnetic part 5 can be installed on the opposite side of the reed switch 1 with respect to the permanent magnets 2 and 3 (see Fig. 2) or in such a way (see Fig. 3) that the soft magnetic part 5 crosses the plane 6 (conditional) passing through the longitudinal axis of the reed switch 1 and perpendicular to the magnetization axis 7 of the permanent magnets 2 and 3.

 The reed switch may contain an additional reed switch 8 (see Fig. 4) located at opposite poles (pole S in Fig. 4) of permanent magnets 2 and 3 with respect to the main reed switch 1 (which is located at the poles N). An additional reed switch 8 is located parallel to the main reed switch 1. The magnetically soft part 5 in such a displacement sensor has a dimension in the direction of the magnetization axes 7 of the permanent magnets 2 and 3 that is larger than the distance between the longitudinal axes of the reed switches 1 and 8.

 In the reed switch of displacement as a reed switch 1 can be used a switching reed switch (see Fig. 5) with breakable contact parts 9, displayed on one side of the cylinder (in Fig. 5 to the right). In such a motion sensor, the switching reed switch 1 is mounted with its closable contact part 10 towards the movable magnetically soft part 5.

 In all versions of the displacement sensor, the soft magnetic part 5 has the possibility of controlled movement along the reed switch 1. In the initial position (Fig. 1-5), it is located opposite the overlap 4 of the contact parts of the reed switch 1.

 Reed switch displacement, for example, in the case of a symmetric magnetic system operates as follows. In the initial position, due to the symmetry of the magnetic system (Fig. 1-4) and the counter-installation of permanent magnets 2 and 3, the magnetic flux passing through the working gap in the overlap area 4 of the contact parts of the reed switches 1 and 8 is zero. At the same time, reed switches 1 and 8 are in their initial, released state (contact details being closed are open). When the magnetically soft part 5 is displaced along the reed switches, for example, to the right, redistribution of magnetic fluxes in the system occurs. This leads to the appearance of a magnetic flux passing through the working gap in the area of overlap 4 of the contact parts created by the left permanent magnet 2 and passing from left to right. At the same time, reed switches 1 and 8 are triggered. In the same way, the reed switches are triggered when the magnetically soft part 5 is displaced to the left.

 When using a switching reed switch (Fig. 5) or an asymmetric reed switch in the sensor, the magnetic system is also asymmetric. Therefore, the initial position of the soft magnetic part 5 relative to the overlap 4 of the contact parts is selected so that its asymmetric position compensates for the asymmetry of the reed switch, as a result of which the magnetic flux in the working gap of the reed switch 1 would be zero. The zero value of the working magnetic flux in the initial position can also be achieved by the asymmetric arrangement of the permanent magnets 2 and 3 relative to the overlap 4 of the contact parts.

 Variants of the displacement sensor in FIG. 2 and FIG. 3 provide an equal arrangement of parts, which allows you to choose the dimensions of the sensor in accordance with the specified operational requirements.

 In the displacement sensor, the reed switches in accordance with FIG. 4. Here you can adjust the trigger points of each reed switch. This allows you to achieve synchronous operation of the reed switches, or vice versa, the necessary difference in the coordinates of the operation in accordance with the specified requirements.

 The proposed displacement sensor has a small travel differential due to a sharp redistribution of magnetic flux when the magnetically soft part 5 is displaced, increased vibration resistance, since in the initial position the magnetic flux in the working gap is zero and the electromagnetic force is completely absent. In addition, the moving control part is not a permanent magnet, but a soft magnetic part, which can often be used as a structural element of a controlled object. This magnetically soft part in the sensor is located on one of its sides, which also expands the scope of its application, in contrast to slot-type sensors.

Claims (5)

 1. Reed relocation sensor containing a reed switch, two rod permanent magnets magnetized longitudinally and mounted perpendicular to the longitudinal axis of the reed switch on one side of it, but from different sides of the contact contact overlap of the reed switch and a magnetically soft part mounted for movement, characterized in that that the rod permanent magnets face the reed switch with the same poles, the magnetically soft part is located on the other side of the reed switch with respect to the permanent magnets with the possibility of moving along flax axis of reed switch.  2. The sensor according to claim 1, characterized in that the soft magnetic and rod parts, permanent magnets are located on different sides relative to the longitudinal axis of the reed switch.  3. The sensor according to claim 1, characterized in that the magnetically soft part is located in such a way that it is crossed by a plane passing through the longitudinal axis of the reed switch and is perpendicular to the magnetization axis of the permanent magnets.  4. The sensor according to claim 1, characterized in that it is equipped with an additional reed switch mounted at opposite poles of the permanent magnets with respect to the main reed switch and parallel to the last, and the soft magnetic part is made so that its length in the direction of the magnetization axes of the permanent magnets is greater than the distance between the longitudinal reed axes.  5. The sensor according to paragraphs. 1 to 4, characterized in that the switching reed switches with disconnecting contact parts located on one side of the cylinder ends are used as reed switches, these reed switches are installed in such a way that a soft magnetic part is located at the end of the reed cylinder cylinders with closing contact parts.

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