RU2145747C1 - Inertia switch - Google Patents

Abstract

FIELD: electromechanical threshold-action inertial sensors. SUBSTANCE: inertia switch has case accommodating permanent magnet, open-circuit contact pair with movable contact in the form of flexible bracket secured on permanent-magnet side, spherical inertia body held in initial position due to magnetic attraction force and mounted for displacement both along bracket and in direction of its crosswise bending. Elastic damping strip is secured on path of inertia body travel at angle φ₀ to bracket surface for increasing this angle during inertia body travel. Angle φ₀ is chosen within the range of 90^o > φ₀ ≥ 2arctg(R/l_s); relationship between elastic bending characteristics of bracket and damping strip is to satisfy condition F_{c min} > 0,5n_a•m•sin(2φ₀+2Δφ), where φ₀ is initial angle between bracket and plate; R is inertia body radius; l_s is length of strip; F_{c min} is minimal force of contact closure; n_a is acceleration along bracket within desired range; m is inertia body mass; Δφ is angle of inclination increased due to inertial force. EFFECT: provision for multiple operation of switch mounted on moving equipment; improved reliability of circuit switching. 2 cl, 2 dwg

Description

 The invention relates to the field of instrumentation, namely to electromechanical inertial sensors of threshold action.

 Known inertial switches / 1,2 /, containing a spherical inertial body held by a permanent magnet, a cylindrical guide channel for the working stroke of the inertial body and a contact pair located at the end of the working stroke of the inertial body with the ability to close contacts through the material of the inertial body.

 Devices [1,2] contain features consistent with the invention: a spherical inertial body housed in a housing held by a permanent magnet, and an open contact pair.

 A common disadvantage of analogues [1,2] is that they can only respond to the acceleration component directed along the axis of the cylindrical guide channel, and when the vibrations are applied along this axis due to vibrations of the inertial body, the contacts can open.

 The prototype is an acceleration sensor [3], which contains a permanent magnet placed in the housing, an open contact pair with a movable contact in the form of an elastic cantilever mounted on the magnet placement side, a spherical inertial body held in its original position by magnetic attraction and mounted to move along the surface cantilevers both along its length and in the direction of its transverse deflection. The contact pair is closed due to the elastic force of the contacting console, provided the inertial body exits at the end of the working stroke beyond the moving edge of the console into free space.

 The device [3] contains features consistent with the invention: a permanent magnet located in the housing, an open contact pair with a movable contact in the form of an elastic cantilever fixed from the side of the magnet, a spherical inertial body held in its original position by magnetic attraction and mounted for movement both along the length of the console, and in the direction of its transverse deflection.

 The functional disadvantage of the prototype [3] lies in the single action, because after one actuation the inertial body does not return to its original position when the inertial forces disappear. The return is prevented by stopping at the free edge of the console.

 The second disadvantage of the prototype is that after operation, the inertial body, being in free space, under the influence of vibration has the ability to hit the edge of the elastic cantilever, which can cause the contact pair to open.

 The task, which is aimed by the claimed technical solution, is to eliminate the above disadvantages of the prototype.

 The technical result obtained by the implementation of the invention is to ensure multiple operation of the switch located on a moving object, while improving the quality of switching an electrical circuit.

 Under the action of two components of inertia forces of a given range, namely due to an increase in the linear velocity of the object and its rotation relative to the longitudinal axis, a closed state of the contact pair should be provided. And in the case of the disappearance of the inertia force directed along the longitudinal axis of the object, the switch contacts must go into an open state. With the reappearance of the inertia force directed along the axis of the object, the contact pair should again go into a closed state, etc.

 At the same time, it is understood that the rotation frequency of the object relative to the longitudinal axis is within predetermined limits.

где φ₀ - начальный угол между консолью и демпфирующей пластиной;
R - радиус сферического инерционного тела;
l_п - рабочая длина демпфирующей пластины;
F_Kmin - заданная минимальная величина поперечной силы, обеспечивающая прогиб консоли для замыкания контактной пары;
n_y - величина составляющей ускорения направленной вдоль консоли, находящаяся в заданном диапазоне;
m - величина массы инерционного тела;
Δφ -- увеличение угла наклона демпфирующей пластины под действием силы инерции F_y-n_y, находящейся в заданном диапазоне.In order to achieve the above technical result, an inertial switch containing a permanent magnet located in the housing, an open contact pair with a movable contact in the form of an elastic cantilever fixed on the magnet placement side, a spherical inertial body held in its original position by magnetic attraction and mounted with the possibility of movement as along the console, and in the direction of its transverse deflection, it is new that an elastic damper is fixed on the path of the working stroke of the inertial body a friction plate at an angle φ ₀ to the surface of the console with the possibility of increasing this angle during the working stroke of the inertial body, and the angle φ _{0 is} made within
90 ^° > φ ₀ ≥2arctg (R / l _p ), (1)
and the ratio of the elastic characteristics of the deflections of the console and the damping plate is selected from the condition:

where φ ₀ is the initial angle between the console and the damping plate;
R is the radius of the spherical inertial body;
l _p - the working length of the damping plate;
F _Kmin - the specified minimum value of the transverse force, providing the deflection of the console to close the contact pair;
n _y is the magnitude of the acceleration component directed along the console, which is in a given range;
m is the mass of the inertial body;
Δφ is the increase in the angle of inclination of the damping plate under the action of the inertia force F _y -n _y , which is in a given range.

In the absence of the axial component of the acceleration n _x (in the "pause"), that is, in the absence of an increase in the linear velocity of the object, a transverse force acts on the contacting console
F _x (Y) = 0.5n _y • m • sin (2φ ₀ + 2Δφ). (3)
An increase in the angle Δφ during the working stroke of the inertial body with increasing n _y limits the growth of F _x (Y), since the function sin (2φ ₀ + 2Δφ) decreases in this case, since the angle φ ₀ + Δφ exceeds 45 ^o . Therefore, as will be shown below when considering the scheme of acting forces, the value of F _x (Y) in the entire specified range of n _y remains less than the minimum value of the force F _{kmin of the} contact pair closure. As a result of this, in the “pause” the contact pair is in the open state. When a specified value acceleration n _x appears after a “pause”, the force acting on the contacting console increases:
F ₂ = n _x • m + F _x (Y)
Under these conditions, F ₂ > F _k , and the contact pair goes into a closed state.

In a given range of values of n _x , n _{y, the} resulting total transverse force F ₂ significantly exceeds the value of F _k , creating additional contact pressure after closing the contact pair, exceeding the possible level of vibration loads, increasing the quality of switching the electrical circuit.

So, for example, at n _x = n _y and φ ₀ + Δφ = 45 ^{°, the} value of F ₂ becomes 1.5 times greater than the value of F _x = n _x • m.

 An additional effect of improving the quality of switching electrical circuits is obtained by performing a damping plate with a bent tongue resting on its free end on the inner surface of the housing with the possibility of sliding along it with a change in the angle of inclination of the damping plate, which is expressed in the damping of vibration due to friction of the tongue on the inner surface of the housing.

In FIG. 1 shows the construction of an inertial switch;
in FIG. 2 shows a diagram of the forces acting on the contact console and the damping plate.

In the figures indicated:
1 - housing
2 - inertial body (ball),
3 - permanent magnet
4 - fixed contact,
5 - elastic contacting console,
6 - elastic damping plate,
7 - the tongue of the damping plate,
8 - the free end of the tongue,
R is the radius of the inertial body,
l _p - the working length of the damping plate,
φ ₀ - the initial angle between the console and the damping plate,
Δφ - change in the angle of inclination of the damping plate during loading,
l _k is the distance from the point of contact of the ball with the damping plate to the place of its attachment,
δ is the value of the contact gap,
F ₂ - the force acting on the contacting console,
F _y - the value of the inertia of the ball obtained from the rotation of the object around the longitudinal axis,
F _x (Y) is a component of the force directed normal to the contacting console,
F _g - the magnitude of the normal force acting on the damping plate,
x is the longitudinal axis of the object,
y is the transverse axis of the object parallel to the contacting console.

 The inertia switch shown in FIG. 1, consists of a housing 1 in which a permanent magnet 3 and a contact pair with a fixed contact 4 and an elastic contacting console 5 fixed in the housing 1 from the side of the magnet 3 are placed. The inertial body 2 is held by the attractive force of the magnet 3. On the path of the inertial body 2 a damping plate 6 is fixed with a bent tongue 7, the free end of which 8 rests on the inner surface of the housing 1.

The damping plate 6 is installed at an angle relative to the contacting console 5 with the possibility of increasing this angle during the working stroke of the inertial body 2. The value of the angle φ _{0 is} selected from condition (1), and the ratio of the elastic characteristics of the deflections of the console and the damping plate is selected from condition (2).

The switch installed in the object operates as follows. At the initial stage of the object’s movement, the linear velocity along the X axis increases from zero to a certain value, at the same time, the object is twisted around the X axis. Under the action of two components of inertia forces F _x = n _x • m and F _y = n _y • m inertial body 2, having overcome the force of magnetic attraction, it breaks away from the supporting surface and makes a working stroke. During the working stroke, the inertial body 2 moves along the length of the contacting console 5, and in the direction of its transverse deflection, exerting a force on the damping plate 6. Moreover, the total force F ₂ = F _x + F _x (Y) -n _x • m + 0.5n _y • m • sin (2φ ₀ + 2Δφ). (see Fig. 2) significantly exceeds the contact closure force F _k , therefore, the contact pair goes into a closed state (in Fig. 1 this state is depicted by dash-dotted lines). When the means of acceleration of the object are turned off, the axial component of acceleration n _x = 0, the rotation frequency of the object is preserved, i.e. F ₂ = F _x (Y), and, as already mentioned above, the force F _x (Y) = 0.5n _y • m • sin (2φ ₀ + 2Δφ) acts on the contacting console.
A contact pair, under such a force action, goes into an open state. When you turn on the acceleration means, the force of influence on the contacting console increases by n _x • m and becomes larger than F _kmax , the contact pair at the same time goes into a closed state.

The force F _k at a given value of the contact gap δ for a cantilever fixed flat spring (see figure 2) can be determined from the relations available in the reference literature (see, for example / 4 /, p. 218).

Since the damping plate 6 with the bent tab 7 touching the wall of the housing 1, when loaded with a force F _g (see Fig. 2), is a static indefinable system, and the value of l _k changes depending on the change in the angle Δφ, the calculated values of the deflection of the plate and angle Δφ can be obtained numerically on a computer or experimentally. Varying the values of the plate thickness, its width and the elastic modulus of the material, one can obtain the parameters of elastic deflection and angle Δφ of the plate 8, satisfying condition (2) in a given range from n _ymin to n _ymax
Sources of information
1. USSR author's certificate N 1820335, G 01 P 15/04, 06/07/93.

 2. US patent N 5193392, H 01 H 35/14, 10/06/92.

 3. The patent of Germany N DE 4106103 H 01 H 35/14, 03/12/92.

 4. Strength, stability, fluctuations. Reference T.1.- M.: Mechanical Engineering, 1968.

Claims (2)

1. The inertial switch containing a permanent magnet located in the housing, an open contact pair with a movable contact in the form of an elastic cantilever, fixed on the side of the magnet, a spherical inertial body held in its original position by the force of magnetic attraction and mounted to move along the length of the cantilever, and in the direction of its transverse deflection, characterized in that an elastic damping plate is fixed at an angle φ ₀ to the surface of the cantilever on the path of the inertial body working stroke whether with the possibility of increasing this angle during the working stroke of the inertial body, and the angle φ _{0 is} made within
90 ^o > φ ₀ ≥ 2 arctan (R / l _p ),
and the ratio of the elastic characteristics of the deflections of the console and the damping plate is selected from the condition
F _kmin > _{0.5n y} • m • sin (2φ ₀ + 2Δφ),
where φ ₀ is the initial angle between the console and the damping plate;
R is the radius of the spherical inertial body;
l _p - the working length of the damping plate;
F _Kmin - the specified minimum value of the transverse force, providing a deflection of the console to close the contact pair;
n _y - the value of the acceleration component directed along the console, which is in a given range;
m is the mass of the inertial body;
Δφ is the increase in the angle of inclination of the damping plate under the action of inertia in a given range.  2. The inertial switch according to claim 1, characterized in that the elastic damping plate is made with a bent tongue, resting its free end on the inner surface of the housing with the possibility of sliding on it with a change in the angle of inclination of the damping plate.

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