RU2292016C1 - Level of liquid signaling device - Google Patents

Abstract

FIELD: inspection and regulation of level of liquid.

SUBSTANCE: level of liquid signaling device has float, magnet mounted on float, lever made for turn around horizontal hinge, float's stroke restrictor and reed mounted for being switched from magnet related to lever. No less than three magnets are related with lever. Magnets are magnetized at the same direction and they are remote from axis of hinge and are mounted with angular shift relative each other. The shift provides continuous area of interaction of float with reed. Moreover float is made rotating and it is integrated with lever into single structure element; as the lever of the second kind is used. Axis of hinge is parallel to axis of magnetization of magnet tightly connected with end of lever, and to axes of reeds mounted for in-turn entry off float into interaction with them and for simultaneous interaction with at least two reeds and as well at situation when float makes contact with restrictor and the interaction is performed with single reed only.

EFFECT: widened functional abilities; widened area of application; reduced sizes; simplified design; improved precision; higher reliability of alarm.

4 dwg

Description

The invention relates to the field of remote control and level control.

Known liquid level detectors operating on the principle of threshold float transducers (EI collection (VINITI) “Testing and measuring equipment”, 1989, No. 15, pp. 7-9, ref. 77), which have a sensitive element in the form of a float with rotary movement and a system of electrical contacts that are triggered by the corresponding movement of the float due to the impact of buoyancy force on it. These float transducers are installed on the side wall of the tank at a height corresponding to the signaling level, and have relatively small dimensions. The use of magnetic coupling in threshold float converters allows the transfer of the actuating force from the float to the contacts through an impermeable wall of non-magnetic material. The liquid level switch, made on the indicated principle, has a float, a permanent magnet rigidly connected to it, a hinge, limiters of maximum displacements of the float in the form of plates, a membrane of non-magnetic material, made in the form of a single unit with a mechanical sealing element, a permanent magnet of the electrical contact system , mounting flange and contact switching mechanism.

However, such a detector is complex in design and not reliable enough due to the presence of a large number of movable elements. In this case, a signal can be output in the flow or refueling mode only at one predetermined liquid level.

The closest adopted for the prototype is a liquid level switch (ed. Certificate. SU No. 1675685, class G 01 F 23/32, 23/56, 23/62).

When the float rises with increasing liquid level in the guide tube, the control magnet built into it interacts with the magnet in the lever cavity, as a result of which the magnet moves in the opposite direction from the pipe, the lever rotates around the hinge and the lever magnet enters into interaction with the reed switch that turns on. When lowering the liquid level and lowering the float, the process occurs in the reverse order, as a result of which the reed switch is turned off.

The known liquid level switch has the following disadvantages.

The limited functionality due to the fact that the execution of the lever and its magnet with relative fixation in the extreme positions creates a relay mode of operation, in which, despite the finite rate of change in the liquid level, the lever must be transferred from one position to another in a minimum amount of time. In this regard, it is impossible to provide signaling of several, for example, two, levels using one lever, since when installing two reed switches with a height offset relative to each other, either almost the same operation of the reed switches or, with an increase in the offset, reliable operation of only one of them.

Its functionality is also limited by the possibility of signaling only in the liquid refueling mode due to the fact that the reed switch must be switched on with a magnet that moves in the opposite direction from the pipe, however this is only possible when the float is raised with a liquid level. Thus, the indicated signaling device cannot be used to issue a signal at a liquid flow rate.

The known detector has at least three movable elements, without taking into account the contacts of the reed switch, and remains structurally complex. The external arrangement, as well as the constructive implementation of the lever with a fixed support in the middle part, characterizing it as a lever of the first kind, increases the dimensions of the device.

The gap between the float and the inner surface of the guide tube, which in such devices should be set to the minimum to ensure effective magnetic interaction, when the float passes through the lever location zone, can be completely selected under the influence of magnetic forces, which will lead to an increase in the friction forces that inhibit the movement of the float , and, as a consequence, to a decrease in the accuracy of signaling a given liquid level.

In addition, the signaling device will not have sufficient reliability when operating in the vehicle tank, where under the influence of mechanical loads such as vibration and shaking, its functioning may be disrupted due to the release of the manitic connection between two movable elements: the lever and the float, which limits the scope of the signaling device to stationary installations.

The basis of the invention is the task of expanding the functionality and scope, reducing the size and simplification of the device, increasing the reliability and accuracy of level signaling.

In order to fulfill the task in a liquid level switch containing a float, a magnet mounted on it, a lever made to rotate around a horizontal hinge, a float travel limiter and a reed switch installed with the possibility of switching on from a magnet connected with a lever new according to the invention, is that at least two magnets magnetized in one direction, equidistant from the hinge axis and mounted with an angular displacement relative to each other, are connected to the lever the interaction zone of the float with the reed switch, the float is rotatable and combined into a single structural element with a lever, the second kind of lever being used, the axis of the hinge parallel to the magnetization axis of magnets rigidly connected to the end of the lever and the axes of the reed switches installed with the possibility of alternating entry the float in interaction with them, simultaneous interaction with at least two reed switches, and also, when the float comes into contact with the limiter, and continues to interact along the edge her least one reed switch.

Due to the fact that at least two magnets are magnetized in one direction, equidistant from the hinge axis and installed with an angular offset relative to each other, providing a continuous area of interaction between the float and the reed switch, the level transmitter's functionality is expanded by expanding the liquid level signaling range and the angle of the signal, and also increases the reliability of level signaling, since the extension of the range of signaling level and angle of the signal excludes the incidence of false switching on and off of reed switches under mechanical loads such as vibration or shaking. This allows you to use the indicator to measure the liquid level on the vehicle, which expands the scope of the indicator.

The execution of the float rotary and combining it into one structural element with a lever, which is used as a lever of the second kind, and the axis of the hinge parallel to the magnetization axis of the magnets and the axes of the reed switches, reduces dimensions, simplifies the device and, at the same time, further increases the reliability of the level switch with the prototype, because the moving element in the design remains one float, and the magnetic connection is maintained only between the float and the reed switches.

When the float rotates, friction forces exist only between the float and the axis, due to the small diameter of which, their braking moment is insignificant compared to the torque, which increases, in comparison with the prototype, the level signal accuracy.

The functionality of the level switch is also expanded due to the presence of a rigid connection of the magnets with the end of the lever, allowing the reed switch to be switched on when this lever arm approaches from below and above, and provides an alarm both at a given refueling and at a flow rate, and at the same time thanks to installation of reed switches with the possibility of alternately entering the float into interaction with them, simultaneous interaction with at least two reed switches, as well as when the float comes into contact with anichitelem, continue his interaction with at least one reed switch, which allows to use one lever in the annunciator liquid level for dispensing a plurality of signals.

For a more complete disclosure of the invention, Fig. 1 shows a cross section of the proposed level switch along a vertical axis, Fig. 2 is a vertical section of a rotary float, and Fig. 3 is a continuous interaction zone between a float and a reed switch. An example of the output of three signals is shown: in Fig. 4a, by two reed switches and in Fig. 4b, by three.

In accordance with Figure 1, the liquid level switch contains a rotary float, magnets 2 mounted on it, a lever with which the float 1 is integrated into one structural element and which is rotatable around a horizontal hinge 3, a casing 4 serving as a limiter to the stroke of the float 1, and reed switches 5, mounted with the possibility of switching on from magnets 2, at least two of which are connected with the lever, magnetized in one direction, equidistant from the axis of the hinge 3 and installed with an angular displacement Δα relative to each other, ensuring ayuschim continuous zone of interaction of the float 1 with the reed 5. As the lever arm of the second kind is used. The axis of the hinge 3 is parallel to the axis of magnetization, for example, rod magnets 2, rigidly connected to the end of the lever, and the axes of the reed switches 5, installed with the possibility of alternately entering the float 1 into interaction with them, simultaneous interaction with at least two reed switches 5, and also, the float 1 coming into contact with the limiter, continuing its interaction with at least one reed switch 5. The hinge 3 is attached to the casing 4 connected to the housing 6 of the signaling device, hermetically mounted on the side wall 7 of the tank. Inside the housing 6, for example, there are two reed switches 5, which can be either spaced apart in height for separate output of two signals, or, at their close arrangement, make up a single contact node, with interconnection, to increase the reliability of operation, in a parallel circuit. Reed switches 5 are connected to the contacts of the electrical connector 8. The inner horizontal plane of the casing 4 secures the float 1 in a horizontal position, and the protrusion 9 of the casing 4 is designed to fix the float 1 in the extreme allotted position at an angle, ensuring its buoyancy. Due to the combination of the float in one structural element with a lever, it is the only movable element in the design of the level switch, and magnetic communication is only between the float and the reed switches.

Figure 1a shows a device for signaling when refueling, and Figure 1b shows a flow rate.

Figure 2 shows a vertical section of a rotary float 1 in a horizontal position, where it is shown that the points of application of the buoyancy force F and gravity P are located on one side of the fixed support - the axis of the hinge 3, so the float in this case is a lever of the second kind. The force of gravity P is shifted relative to the force F to the end of the lever (applied to its longer shoulder), due to the relatively large specific gravity of the magnets 2, rigidly connected to the end of the lever. In this case, the float 1 is made with a predominance of force F so that its torque provides positive buoyancy of the float.

Figure 3 shows:

- on the graph "a" - the dependence of the magnetic field H in the working gap of the reed switch on the angle of rotation α of the float with one magnet and the angle of the signal (α _off -α _on ), depending on the strength of turning H _on and off H _{off the} reed switch;

- on the graph "b" - two similar relationships for each of the two magnets installed with an angular displacement Δα relative to each other;

благодаря применению двух магнитов в поплавке, расширяется более чем в два раза; при этом указанные на графике обозначения углов α_Н, α_Г, α_В соответствуют углу отклонения от вертикали нижнего, горизонтального и верхнего положений поплавка.- on the graph "c" - the result of summing the intensity of two magnets magnetized in one direction, from which it is obvious that the angle of the signal

thanks to the use of two magnets in the float, it expands more than twice; while the designations of the angles α _Н , α _Г , α _В indicated on the graph correspond to the angle of deviation from the vertical of the lower, horizontal and upper positions of the float.

The liquid level switch shown in Figa, works as follows. There is no liquid in the initial state, and the float 1 of the signaling device is in its lowest position. In this case, the float 1 rests on the protrusion 9 of the casing 4 and is outside the zone of interaction with the reed switches 5, which, in this example, are considered as a single contact node, and are currently in the off state. This position of the float corresponds to the lowest possible angle of deviation from the vertical α _H in the graph of Figure 3, in which the magnetic field H in the working gap of the reed switches tends to zero. When the liquid level rises and its contact with the float 1, the buoyant force F applied to the point of the float 1 shown in Fig. 2 and directed vertically upward starts to grow from zero and when its torque exceeds the moment of gravity P, the float 1 will move away from protrusion 9 and begins to rotate around the hinge 3 in the direction of the housing 6. as the closest approach thereto of the magnets 2 successively engages with the reed switches 5, when the angle α is turned _oN the reed 5 in which the gap magnetic field strength dos _On the needle of H, and outputs a resulting alarm signal. With a further turn of the float 1 and an increase in tension, along with the first reed switch 5, the second is switched on, thereby increasing the reliability of signal output. A further increase in the liquid level and the rotation of the float 1 up to a horizontal position does not change the on state of the reed switches 5, since, in accordance with FIG. 3, c, during the rotation and at an angle α _{G, the} tension N remains above the value of H _on . The signal is maintained even with a further rise in the liquid level, since the float 1 is fixed in a horizontal position by the inner plane of the casing 4. When the detector is in the tank of the vehicle and the float 1 can be separated from this plane under the influence of mechanical loads, the probability of a false signal turn off is close to zero due to the use of two magnets 2, magnetized in one direction, equidistant from the axis of the hinge 3 and installed with an angular displacement Δα relative to each other, providing reryvnuyu interaction zone of the float 1 with each of the reed 5, and substantially largest angle (α -α _{T OFF)} of reverse rotation in a liquid, which would have to make the float 1 before the shutdown signal.

положения поплавка включаются герконы 5 и производится выдача сигнала сигнализатором, которая сохраняется при достижении горизонтального - предельно низкого положения поплавка, под углом α_Г, а также дальнейшем понижении уровня жидкости. При пустом баке транспортного средства и кратковременном отрыве поплавка 1 от внутренней плоскости кожуха 4 под влиянием механических нагрузок, вероятность ложного выключения сигнала близка к нулю, благодаря значительному по величине углу

обратного поворота, который бы пришлось совершить поплавку до момента выключения.The operation of the indicator depicted in Fig.1b also in the position corresponding to an empty tank, in the case of fluid flow occurs similarly. With a full tank, the buoyancy force F, see Figure 2, is maximum and exceeds the gravity P, and the float 1 rests on the protrusion 9, see Figure 1, which corresponds to the maximum upper angle α _B in the graph of Figure 3, c. When lowering the liquid level to the float, starting from a certain point in time, the force F begins to decrease and, when its torque becomes less than the moment of force P, the float 1 will come out of contact with the protrusion 9 and will begin to rotate around the hinge 3 towards the housing 6. Starting from the corner

the position of the float, the reed switches 5 are turned on and a signal is issued by the signaling device, which is maintained when the horizontal - extremely low position of the float is reached, at an angle α _Г , as well as a further decrease in the liquid level. With an empty tank of the vehicle and a short breakaway of the float 1 from the inner plane of the casing 4 under the influence of mechanical stresses, the probability of a false switching off of the signal is close to zero, due to the significant angle

the reverse rotation that the float would have to make before turning it off.

при расходе, которая будет соответствовать заданному уровню выдачи сигнала.When calculating the installation height of the level switch on the side wall 7 of the tank, they are guided by the position of the buoyancy line on the float 1 when it reaches an angle α _on when refueling or angle

at a flow rate that will correspond to a given level of signal output.

To give several, for example, two signals from independent reed switches 5 at different levels, the float 1 in the process of turning towards the horizontal position alternately interacts with the reed switches 5, then simultaneously interacts with two reed switches, and when it comes into contact with the casing 4, acting as a limiter, continues to interact with at least one reed switch. As a result, two zones of signal output are formed at the given angles of the position of the float α ₁ , α ₂ shown in Fig. 4a, for example, for the refueling mode. At the end of a full refueling, only reed switch 5 remains closest to the horizontal axis of the indicator. In this case, the issuance of two signals at the α ₂ -α ₃ site is simultaneously used as an additional signal about the liquid level and, thus, the three signals are provided by two reed switches.

The issuance of all signals with a given condition for their conservation during further movement of the liquid level beyond the limiter is achieved due to the achieved more than doubled the angle of interaction of the float with the reed switch, shown in Figure 3. In this case, zones of signal output are formed, for example, by three reed switches at the angles of the position of the float α ₁ , α ₂ , α ₃ shown in Fig. 4b, for example, for the flow mode.

Compared with the prototype, the ability of the proposed detector to work both when refueling and at a flow rate, as well as issuing several signals, expands its functionality. Reducing the number of magnetic bonds, as well as moving elements in the structure increases the reliability of the signaling device. The installation in the float of at least two magnets magnetized in one direction, with an angular displacement relative to each other, providing a continuous increased zone of interaction between the float and the reed switches, reduces the likelihood of false on and off signals under mechanical loads when working in a vehicle tank, for example, vibration acceleration up to 98.1 m / s ² and shock up to 117.6 m / s ² , increases reliability and expands the scope of the liquid level switch.

Thanks to the use of a lever of the second kind as a lever, as well as making the float rotary and combining it with the lever into one structural element, the device is simplified and the dimensions of the liquid level indicator are reduced. At the same time, friction is maintained only on the axis of the float, which does not impede its free rotation and ensures signal accuracy in accordance with the standards for float alarms. The manufactured and tested samples of the signaling device have dimensions not exceeding (80 × 50 × 50) mm ³ , the length of the off-side part along the horizontal axis is not more than 30 mm, and the error in signaling the liquid level does not exceed ± 4 mm.

The use of this detector does not require complex hardware and software.

Claims (1)

A liquid level switch comprising a float, a magnet mounted on it, a lever rotatable around a horizontal hinge, a float travel limiter and a reed switch mounted to be switched on from a magnet connected to the lever, characterized in that at least two magnets are connected to the lever magnetized in one direction, equidistant from the hinge axis and installed with an angular displacement relative to each other, providing a continuous zone of interaction between the float and the reed switch, the float is made n rotary and combined into one structural element with a lever, which is a lever of the second kind, the axis of the hinge parallel to the magnetization axis of magnets rigidly connected to the end of the lever, and the axes of the reed switches installed with the possibility of alternately entering the float into interaction with them, simultaneous interaction at least with two reed switches, as well as when the float comes into contact with the limiter and continues its interaction with at least one reed switch.

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