RU152828U1 - CAPACITIVE LIQUID SENSOR - Google Patents

Abstract

1. A capacitive liquid level sensor, including a sensor housing and capacitor electrodes located therein, connected to the connecting wires, characterized in that the capacitive sensor has a sealed protective shell in the cavity of which the sensor housing is located, and that the sealed protective shell is made of plastic resistant to aggressive liquids, and the fact that the connecting wires have a protective plastic sheath, resistant to aggressive liquids, and the fact that a sealed protective shell ka has attachment means to rezervuaru.2. A capacitive liquid level sensor according to claim 1, characterized in that the sealed protective sheath is made of plastic resistant to aggressive liquids, which isotactic polypropylene used. 3. The capacitive liquid level sensor according to claim 1, characterized in that the sealed protective sheath includes a cylindrical pipe, the lower end of which is hermetically connected to the end cap, and the upper end of which has a screw cap with an opening through which the connecting wires are passed to ensure tightness, additionally coated with a screw cap protective agent resistant to aggressive liquids. 4. A capacitive liquid level sensor according to claim 1, characterized in that the sensor housing is cylindrical, and the outer diameter of the sealed containment is selected within 1.2-1.4 of the diameter of the sensor housing. 5. Capacitive liquid level sensor according to claim 1, characterized in that the means for attaching the protective shell to the tank are made in the form of spring-loaded latches, adapt�

Description

The technical field to which the utility model belongs.

The utility model relates to liquid level indicators, namely, to capacitive liquid level sensors, including a sensor housing, and capacitor electrodes located therein, connected to connecting wires, and can be used to measure the level of liquid aggressive environments.

In this description and in the formula there are spatial terms “upper” and “lower”, which are used everywhere to simplify the understanding of the design, and serve solely for the purpose of designating some details, and not their spatial orientation. The spatial orientation does coincide with these terms when the device is parallel to the force of gravity when it is in the working state. But it is obvious that outside the operating state, for example, during storage or transportation, these parts can be oriented arbitrarily.

The level of technology.

The liquid level is most often measured by float sensors, the basis of which is a conductive ball, which, moving under the influence of a change in the liquid level, closes the contacts. But this design has a low reliability - mechanical movements can be hindered by possible sticking of the ball in one of the positions.

Capacitive sensors, which are expanded capacitor plates sensitive to changes in the conductivity of the environment, are deprived of this drawback. As soon as a liquid appears, or its properties change, this changes the dielectric constant of the medium, which changes the capacitance of the capacitor. It is especially convenient to use such capacitive liquid level sensors to measure the level of aggressive media. Since this reduces the contact of the sensor with aggressive fluid.

So known from the prior art capacitive liquid level sensor, including the sensor housing, and the capacitor electrodes located therein, connected to the connecting wires, see the description of the invention of the Russian Federation No. 2520961, published in 2014.

This device is the closest in technical essence to the claimed utility model and is taken as a prototype for the proposed utility model.

The disadvantage of this device is the inconvenience of operation due to the fact that such a sensor is installed while filling the cavities between the output unit and the external electrode, between the electrodes, and the smaller electrode with plasticized epoxy resin, which makes it impossible to repair and replace it. In addition, such a sensor does not have specifically means of attachment to the tank, which also leads to inconvenience of operation. Another disadvantage of such a sensor is that it is attached directly to the tank wall, which greatly complicates the process of replacing the sensor in case of failure, especially when it comes to wastewater tanks that are completely buried in the ground and access to the walls of such a tank outside is impossible.

Disclosure of a utility model.

The present utility model, based on this original observation, mainly aims to propose a capacitive liquid level sensor, including a sensor housing, and capacitor electrodes located in it, connected to connecting wires, allowing at least to smooth at least one of the above disadvantages, and namely, to provide increased ease of use while ensuring high reliability, which is the technical task of the proposed utility model.

To achieve this, the capacitive sensor has a sealed protective shell, in the cavity of which the sensor housing is located. Sealed protective shell made of plastic, resistant to aggressive liquids. The connecting wires have a protective plastic sheath that is resistant to aggressive liquids. The sealed containment has at least one means of attachment to the reservoir.

Thanks to such advantageous characteristics, it becomes possible to completely isolate the sensor from the effects of aggressive liquid medium, protect the connecting wires, and additionally attach the protective sheath with the sensor to the tank, with the possibility of easily replacing it.

The predominantly sealed containment is made of plastic that is resistant to aggressive liquids, which uses isotactic polypropylene.

Thanks to this advantageous characteristic, it becomes possible to use the unique properties of such a material as resistance to aggressive liquids and availability in order to make a protective shell out of it.

The predominantly hermetic protective sheath includes a cylindrical pipe, the lower end of which is hermetically connected to the end cap, and the upper end of which has a screw cap with a hole through which the connecting wires are passed to ensure tightness, additionally coated with a screw cap protector that is resistant to aggressive liquids .

Due to this advantageous characteristic, it becomes possible to use existing products in the form of polypropylene pipes as the main structural elements of the protective shell, which simplifies the manufacture. And also this makes it possible to provide access to the cavity of the containment for repair and replacement of the sensor due to the presence of a screw cap. It also makes it possible to adapt the length of the containment to a specific tank, since to adjust the length you just need to cut a piece of polypropylene pipe of the appropriate size.

There is a variant of the utility model in which the sensor housing is cylindrical, and the outer diameter of the sealed containment is selected within 1.2-1.4 of the diameter of the sensor housing.

Thanks to this advantageous characteristic, it becomes possible to ensure the performance of a capacitive sensor. Indeed, when the outer diameter of the sealed containment is less than 1.2 of the diameter of the sensor housing, the thickness of the containment becomes very thin, and the risk of damage to it increases. When the outer diameter of the sealed containment is greater than 1.4 from the diameter of the sensor housing, the response distance of the capacitive sensor becomes less than the distance to the liquid, and it will no longer respond to changes in the external environment.

Advantageously, the means for attaching the protective sheath to the tank is made in the form of spring-loaded latches adapted for fastening on a vertical pipe rigidly connected to the tank.

Thanks to this advantageous characteristic, the possibility of simple fastening with the ability to move and detach the protective sheath to a pipe specially installed in the tank appears. This makes it possible to easily configure the sensor to operate at a certain level of liquid in the tank and fix it in this position. If necessary, you can instantly rebuild the sensor to operate at a different liquid level.

There is a variant of the utility model in which the protective means of the screw cap is made in the form of a heat-shrinkable tube made of thermopolymers, which are compressed under the influence of temperature.

Thanks to this advantageous characteristic, it becomes possible to additionally seal the upper part of the protective sheath and connecting wires from the effects of aggressive liquids.

There is a variant of the utility model in which the protective means of the screw cap additionally has an adhesive layer.

Thanks to this advantageous characteristic, it becomes possible to create another additional layer of sealing of the upper part of the protective sheath and connecting wires from exposure to aggressive liquids.

The set of essential features of the proposed utility model is unknown from the prior art for devices of similar purpose, which allows us to conclude that the criterion of "novelty" for the utility model is met.

A brief description of the drawings.

Other distinguishing features and advantages of the utility model clearly follow from the description below for illustration and not being restrictive, with reference to the accompanying drawings, in which:

- figure 1 schematically depicts a functional diagram of a capacitive liquid level sensor according to a utility model.

- figure 2 shows the stages of installation and operation of a capacitive liquid level sensor according to a utility model.

According to figure 1, a capacitive liquid level sensor includes a sensor housing 1, and capacitor electrodes 2 located therein, connected to the connecting wires 3. The capacitive sensor has a sealed protective sheath 4, in the cavity 5 of which the sensor housing 1 is located. Sealed protective shell 4 can be made of plastic that is resistant to aggressive liquids. The connecting wires 3 have a protective plastic sheath 6, resistant to aggressive liquids. Sealed protective shell 4 has at least one means of fastening 7 to the reservoir 8.

Sealed protective shell 4 can be made of plastic that is resistant to aggressive liquids, which is used isotactic polypropylene.

The hermetic protective sheath 4 includes a cylindrical pipe 41, the lower end of which is hermetically connected to the end cap 42, and the upper end of which has a screw cover 43 with an opening through which the connecting wires 3 are passed to ensure tightness, additionally coated with protective means 9 of the screw cover 43 resistant to aggressive liquids.

The housing of the sensor 1 can be made cylindrical, and the outer diameter of the sealed protective shell 4 is selected within 1.2-1.4 of the diameter of the housing of the sensor.

The means of attachment 7 to the reservoir 8 of the protective sheath 4 can be made in the form of spring-loaded latches adapted to be mounted on a vertical pipe 10, rigidly connected to the reservoir 8.

The protective means 9 of the screw cover 43 can be made in the form of a heat-shrinkable tube made of thermopolymers, which are compressed by the action of temperature. The protective means 9 of the screw cap 43 may further have an adhesive layer.

The fluid in figure 1 is designated as 11.

Implementation of a utility model.

A capacitive liquid level sensor is installed and used as follows. An example of the use of a utility model is provided, which is descriptive and does not limit the use of a utility model. According to figure 2:

Stage A1. A capacitive sensor is located inside the cylindrical pipe 41 of the sealed containment 4.

Stage A2. The lower end of the cylindrical pipe 41 is hermetically connected to the end cap 42.

Stage A3. The upper end of the cylindrical pipe 41 is closed with a screw cap 43 with an opening through which the connecting wires 3 are passed.

Stage A4. Ensure the tightness of the upper connection, additionally covering with a protective means 9 of the screw cover 43. For this, the protective tool 9 of the screw cover 43 is made in the form of a heat-shrinkable tube, from which a piece of the required length is cut, it is installed at the upper end of the cylindrical pipe 41 with a small outlet to both and they heat it with an electric hairdryer. You can use a heat-shrinkable tube with a shrink coefficient of 6: 1 (the difference between the diameter before shrinkage and the smallest possible diameter after shrinkage) and with an adhesive layer that provides additional tightness.

Stage A5. The mounting vertical pipe 10 is lowered into the tank, to which it is attached using spring-loaded latches adapted to fasten the sealed protective sheath 4 to the vertical pipe 10.

Stage A6. A sealed protective shell 4 with a capacitive sensor located inside it is located at the depth of the tank 8 at which the capacitive sensor should operate.

Stage A7. Now you can use the device to determine the liquid level in the tank - the capacitive sensor will respond to a change in the environment around it, that is, when the tank is full or when it is empty. Also, a capacitive sensor will respond to changes in fluid composition. For example, as soon as the liquid level 11 rises to the level of electrodes 2, the sensor will trigger and send a signal through wires 3.

Industrial applicability.

The proposed capacitive liquid level sensor has a clear purpose, can be carried out by a specialist in practice and, when implemented, ensures the implementation of the declared purpose. The possibility of being implemented by a specialist in practice follows from the fact that for each feature included in the utility model formula based on the description, the material equivalent is known, which allows us to conclude that the criterion of “industrial applicability” for the utility model is met, as well as the criterion of “completeness of description” utility model.

In accordance with the proposed utility model, on behalf of the applicant Alta Group LLC, a prototype of a capacitive liquid level sensor was manufactured, which was installed on the produced sewer station.

The prototype was made on the basis of a capacitive sensor, the body of which was a cylinder with a diameter of 30 mm, placed in a protective sheath, which was a polypropylene pipe with an external diameter of 40 mm, an internal diameter of 33 mm, the lower end of which was hermetically connected to the end cap, and the upper end of which had a screw cap with a hole through which connecting wires were passed to ensure tightness. The screw cap together with the connecting wires was additionally sealed using a heat-shrinkable tube with a shrink coefficient of 6: 1, which was made of thermopolymers that change shape under the influence of temperature, namely they are compressed. A piece of tube (about 10 cm) was used, mounted on top of a screw cap with a small outlet on either side of it, heated by an electric hairdryer, after which it cooled down, pressing parts. Additionally, the seal was provided with an adhesive applied to the heat-shrinkable tube.

The pilot operation of this utility model showed that such a design provides:

- improving the usability of the proposed device due to the ability to conveniently configure its placement inside the tank,

- simplicity in action if replacement is necessary,

- high reliability due to the presence of a hermetic protective shell adapted to aggressive fluids,

- the ability to quickly change the function of the sensor - simply moving it along the mounting pipe turns it from a low-level sensor to a high-level sensor.

Thus, due to the fact that the capacitive sensor has a sealed protective shell, in the cavity of which the sensor housing is located, and the sealed protective shell is made of plastic that is resistant to aggressive liquids, the connecting wires have a protective plastic shell that is resistant to aggressive liquids moreover, the sealed protective shell has at least one means of attachment to the tank and the technical result is achieved, namely: improving the usability when providing During high reliability.

Additional technical result achieved:

- ease of installation,

- the availability of materials for the manufacture of utility models.

Thus, it is recommended to use the proposed capacitive liquid level sensor to install it both in sewage tanks of domestic sewers, and industrial with a high content of aggressive environments in wastewater.

Claims (7)

1. A capacitive liquid level sensor, including a sensor housing and capacitor electrodes located therein, connected to the connecting wires, characterized in that the capacitive sensor has a sealed protective shell in the cavity of which the sensor housing is located, and that the sealed protective shell is made of plastic resistant to aggressive liquids, and the fact that the connecting wires have a protective plastic sheath, resistant to aggressive liquids, and the fact that a sealed protective shell ka has means of fastening to the reservoir. 2. A capacitive liquid level sensor according to claim 1, characterized in that the sealed protective sheath is made of plastic resistant to aggressive liquids, which isotactic polypropylene used. 3. A capacitive liquid level sensor according to claim 1, characterized in that the sealed protective sheath includes a cylindrical pipe, the lower end of which is hermetically connected to the end cap, and the upper end of which has a screw cap with an opening through which the connecting wires are passed to ensure tightness, additionally coated with a protective screw cap, resistant to aggressive liquids. 4. A capacitive liquid level sensor according to claim 1, characterized in that the sensor housing is cylindrical, and the outer diameter of the sealed containment is selected within 1.2-1.4 of the diameter of the sensor housing. 5. A capacitive liquid level sensor according to claim 1, characterized in that the means for attaching the protective sheath to the tank are made in the form of spring-loaded latches adapted to be mounted on a vertical pipe rigidly connected to the tank. 6. A capacitive liquid level sensor according to claim 3, characterized in that the protective means of the screw cap is made in the form of a heat-shrinkable tube made of thermopolymers, which are compressed under the influence of temperature. 7. A capacitive liquid level sensor according to claim 3, characterized in that the protective means of the screw cap further has an adhesive layer.

Images