RU2519956C1 - On-off and switching mechanism - Google Patents

Abstract

FIELD: electricity.SUBSTANCE: main structural component of a mechanism is a parallelepiped-shaped case square in its cross-section reacting to the atmospheric pressure. The case is made by moulding of an air-tight elastic resilient material, and it has four solid faces, fours elastic edges and two elastic domes instead of two end faces. The case is sealed and when vacuum is created it acts as a four-bar linkage deformed by the atmospheric pressure force into a rhomboidal parallelepiped with a sharp angle of 45°. Current-carrying rods and contacts are moulded into four edges of the parallelepiped. When the rectangular parallelepiped is deformed to the rhomboidal one, the contacts of the four rods are closed by pairs and switch on two electric circuits. The parallelepiped is switched off or reswitched by hand deforming back to the rhomboidal parallelepiped with an angle of 45°. Due to the variable volume of the parallelepiped the atmospheric pressure acts on it as a spring making its jump-like turning to 90°. At that the other two pairs of contacts are closed and the other two electric circuits are switched on. Thus, the atmospheric pressure force ensures required contact pressing, follow-through and roll, large velocity of contacts separation and a large gap between them.EFFECT: design of a simple and producible mechanism ensuring high arc-suppressing capacity and safe and reliable switching of electric circuits in different operating conditions.6 dwg

Description

The invention relates to mechanisms of electrical contact switching devices, producing on-off and switching of electrical circuits in all areas of technology, industry, transport and in everyday life.

There are many different mechanisms for electrical contact switching devices. All of them are inherent in some negative qualities, which are described below:

1) The mechanisms contain many details of complex design and high complexity - springs, levers, cams, etc. (see A.F. Krainev. Dictionary-reference book on mechanisms. - M :, Engineering. 1987. P. 50, 62, 219).

2) In the mechanisms of contact switching devices, at certain voltages and currents, electric sparks and arcs appear, representing a large fire and explosion hazard.

3) Moisture, dust and dirt can penetrate into the mechanisms of switching devices without special protection, causing corrosion of parts, increased wear of contacts and reducing the reliability and service life of switching devices.

Among the existing mechanisms of electrical switching devices, there are no analogues to the mechanism proposed by this invention.

The aim of this invention is to provide an on-off and switch mechanism that is simple in design, technologically advanced in production and provides safety and reliability in various operating conditions.

The goal is achieved through two factors:

1. A natural phenomenon is used as the acting force - atmospheric pressure, which is everywhere and always.

2. The main structural element of the mechanism - the body that responds to atmospheric pressure, is the geometric shape of the box with the introduction of the following features:

a) four parallel faces in cross section form a square,

b) the ribs act as hinges,

c) two end faces are replaced by elastic domes,

d) all parts of the box are made of an airtight material (e.g. rubber).

Due to these features, the parallelepiped is able to act as a hinged four-link (see II Artobolevsky "Theory of mechanisms and machines." - M .: Publishing House. Science. 1988).

The box is a sealed enclosure that allows you to create a certain vacuum in it. When creating a vacuum, the casing under the influence of atmospheric pressure is deformed from square to rhomboid and directly without any details performs the work of an electrical switching device.

The design of the sealed enclosure of the parallelepiped, which is essentially the proposed mechanism, is presented in figures 1, 2 and 3: in figure 1 - in an idle static state, in figures 2 and 3 - in the working state of the rhomboid parallelepiped.

Four parallel faces 1 are links of the hinge mechanism, ribs 2 are hinges, two end faces are replaced by domes 3, a rubber valve 4 is installed on one side for pumping and pumping air, similar to valves used in soccer and volleyballs.

In one face during pressing, a handle 8 is formed to turn on / off and switch the mechanism. At the midpoints of the four faces, conductive metal rods 5 with contact springs 6 and contacts 7, indicated in letters 1, 2, 3 by letters a, b, c, d, are pressed in. The sealed box body is made by pressing from an airtight elastic, elastic material (for example rubber) with the vulcanization of the feedstock.

Vulcanization provides the required properties of the parts of the body: all parts - heat resistance and cold resistance; four faces - hardness; ribs and end domes - elasticity and resilience. Pressing provides sealing of the installation sites of the rods 5 and forms a hole for the valve 4.

The mechanism is illustrated by the diagrams of figure 4, in which it is presented in the form of a hinged four-link. The designations on the diagrams correspond to the designations of structural elements in figures 1, 2, 3, namely: 1 - four links (faces), 2 - four hinges (ribs), 8 - switch on and switch.

In the diagram of FIG. 4a, the mechanism is shown in a static, inoperative state: its cross section is square, the internal volume V _{1 is} proportional to the square area S ₁ . The mechanism is in a state of stable equilibrium, because both outside and inside it is atmospheric pressure.

To bring the mechanism into working condition, it is necessary to pump out part of the air through valve 4. In this case, a dual process occurs in the mechanism (parallelepiped).

a) A certain vacuum is created, and under the influence of atmospheric pressure, the mechanism is deformed from square to rhomboid, the end domes are pulled inward, lengthening in the direction of the large diagonal of the rhombus, and do not impede the parallelepiped deformation (see Fig. 2 and the diagram of Fig. 4b).

b) The rhomboid shape has a volume less than square, the density of the air inside increases and at any stop of pumping the air there is a balance between atmospheric pressure and the air pressure inside, and the deformation of the mechanism stops.

The air is pumped out until the sharp angle of the rhombus becomes equal to 45 °.

At this moment, the cross-sectional area of the parallelepiped S ₂ = S ₁ · sin 45 °,

sin 45 ° = 0.707; then the volume V ₂ proportional to the area S ₂ is

V ₂ = V ₁ × 0.707, i.e. decreased rounded by 0.3 relative to the volume inoperative.

In this position, when the acute angle of the rhombus reaches 45 °, the mechanism works like an electric switching device, closing the contacts 7 in pairs, indicated in FIG. 2 by the letters a-b and d-c, which include two electrical circuits. To switch the mechanism from one on position (see Fig. 2 and the diagram of Fig. 4b) to another (see Fig. 3), an external force F (for example, the strength of a person’s hand, see Fig. 4c) must be applied to the handle 8.

The force F at the first moment overcomes the initial force of atmospheric pressure, which arose earlier during the pumping of air and deformation of the parallelepiped into a rhomboid, which reduced its volume by 0.3.

Therefore, the initial atmospheric pressure force acting on the edge of the mechanism is 0.3 of the total atmospheric pressure equal to 1.033 kg / cm ² , i.e. rounded equal to 0.3 kg / cm ² .

After overcoming this pressure under the action of force F, the mechanism rotates counterclockwise, while the volume of the parallelepiped and the degree of vacuum inside it increase, which causes an increase in the atmospheric pressure acting on it.

At the moment when the shape of the parallelepiped becomes square, its volume also increases by 0.3 (as indicated above), the degree of vacuum inside also increases by 0.3, and the effect of atmospheric pressure becomes maximum (see the diagram of FIG. 4d). At this moment, the position of the parallelepiped is unstable, and it jumps into the second position of stable equilibrium, making a stepwise rotation counterclockwise by 90 ° (see the diagram of Fig. 4e and Fig. 3).

Thus, at the moments of switching off and switching the mechanism, atmospheric pressure acts on it like a spring due to the changing volume of the parallelepiped. In the second equilibrium position, the mechanism also works as an electric switching device, closing the contacts 7 in pairs, indicated in FIG. 3 by the letters a-d and b-c, which include two other electrical circuits.

Thus, this mechanism, which has four contact rods, is capable of switching four electrical circuits. If a particular electrical apparatus is intended for switching only one electrical circuit, then contact rods with the contacts indicated in FIG. 1 by the letters d-g can be omitted. Instead, when pressing the parallelepiped, two stops of the same length are formed.

The proposed mechanism provides important parameters for electrical contact switching devices: pressing contacts, contact failure, rolling of contacts, solution (gap) between contacts, as well as the arcing ability of the switching device (see B.K.Bul et al. Fundamentals of the theory of electrical devices. - M .: Higher school 1970. L. A. Rodstein. Electric devices. - L.: Energoatomizdat. 1989).

Pressing the contacts, the failure of the contacts and rolling of the contacts 7 are created due to the deflection of the contact springs 6 (see figures 1, 2, 3). To obtain a deflection, the length of the contact rod 5 together with the contact spring 6 and the contact 7 is such that when switched on, the contacts are touched pairwise at a rhomboid parallelepiped angle greater than the final angle of 45 °, for example, at angles of 50 ° -52 °. In this case, when the angle is reached 45 ° due to the influence of atmospheric pressure forces, the contact springs bend, which provides the necessary pressure, failure and rolling of the contacts.

The indicated atmospheric pressure forces are determined according to the scheme (Fig. 5).

For example, figure 5 on the left shows a diagram of a sealed enclosure - parallelepiped, shown in figure 1. At the face of the casing, atmospheric pressure forces are indicated by the vectors P _a , which are directed perpendicular to each face to its midpoint. The length of each vector P _a corresponds to the scale: 1 kg of force - 1 cm of length.

Figure 5 on the right shows the same vectors and their summation according to the parallelogram rule. The total vector P _k , which is the contact pressing force, is defined as the double leg of the right triangle with the hypotenuse P _a and angle β ± / 2 according to the formula: P _k = 2P _a · cos β / 2 = 2Р _а · cos 67.5 ° = 2Р _a 0.3827.

The magnitude of the vectors P _and - is atmospheric _pressure acting on the face of the box when the deformation of the square to a rhombus romboidny angle of 45 °.

The current atmospheric pressure is proportional to the change in the volume of the parallelepiped and at a diamond angle of 45 ° it is 0.3 of the total atmospheric pressure of 1.033 kg / cm ² .

So the magnitude of each vector P _a is: P _a = 0.3 · 1.033 · S _g , rounded off P _a = 0.3 · S _g , where S _g is the area of one face, cm ² . The area of each face of the box shown in figure 1, equal to 9 cm ² . The magnitude of the vector P _a = 0.3 · 9 = 2.7 kg.

The pressing force of the contacts in the mechanism shown in figures 1, 2, 3, is determined by the above formula: P _to = 2 · P _a · cos β / 2 = 2 · 2.7 · 0.3827 = 2.052 kg

The arcing ability of the switching apparatus having the proposed mechanism is confirmed by the circuit in Fig.6, which shows the trajectories of two diverging contacts a, b (see figures 1, 2, 3). These trajectories are parts of circles with radii R ₁ , R ₂ and centers O ₁ , O ₂ .

Since the motion of both contacts occurs simultaneously along diverging trajectories, the speed of their divergence and the final solution (gap) between them are large, which provides a high arcing ability of the switching apparatus.

A brief description of the drawings.

Figure 1.

The on-off and switch mechanism for the electrical switching device is a square parallelepiped in a static idle position.

Figure 2.

The on-off mechanism in one working position is a rhomboid parallelepiped with two pairs of closed contacts.

Figure 3.

The on-off mechanism in another operating position is a rhomboid parallelepiped with two other pairs of closed contacts.

Figure 4.

Schemes of the articulated four-link explaining the operation of the mechanism when turning on / off (switching) the switching apparatus.

Figure 5.

The scheme of the articulated four-link with vectors - atmospheric pressure forces providing the necessary parameters of the switching apparatus.

6.

A four-link articulated circuit showing the motion paths of two disconnected contacts when the switching apparatus is turned off (switched).

Claims (1)

The on-off and switch mechanism for electrical contact switching devices, characterized in that the acting force is atmospheric pressure, which acts on the sealed enclosure - a square box made of airtight material with four solid faces, four elastic elastic ribs, two end elastic domes and four current-carrying rods pressed into the face with contact springs and contacts, so that when the air is evacuated and a vacuum is created, it acts as a hinged four-link, which is deformed by atmospheric pressure into a rhomboid parallelepiped with an acute angle of 45 ° , closing four contacts in pairs and including two electrical circuits, and then, when switched on or switched by a person’s hand, it is deformed in the opposite direction again into a rhomboid parallelepiped with an angle of 45 ° , and due to the changing volume of the parallelepiped atmospheric pressure acts on it like a spring, forcing l step-by-step rotation through 90 °, closing two other pairs of contacts and including two other electrical circuits, while the atmospheric pressure provides the necessary contact parameters - pressing, dip and rolling, as well as high arcing ability due to the large values of the speed of contact and solution divergence (gap) between them.

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