RU83481U1 - ELECTROCHEMICAL SIGNALING LEVEL OF ACCESSIBLE SEAWATER SEA WATER - Google Patents

Abstract

1. An electrochemical signaling device for incoming sea water, comprising an outer vertical casing in the form of a pipe and a sealed hollow rod coaxially installed in it with level sensors located along the height of the rod, characterized in that gas diffusion air electrodes mounted in the bottom and walls are taken as level sensors hollow rod, the cavity of the rod communicates with the air environment, the housing is made of insulating material and contains a metal electrode in the lower part. ! 2. The signaling device of claim 1, characterized in that the air electrodes are located on the walls of the hollow rod with overlap. ! 3. The detector according to claim 1, characterized in that the metal electrode is made of aluminum alloy. ! 4. The detector according to claim 1, characterized in that the air electrode mounted in the bottom of the hollow rod is made flat. ! 5. The detector according to claim 1, characterized in that the air electrode mounted in the bottom of the hollow rod is made convex down. ! 6. The signaling device according to claim 1, characterized in that an air pipe with a siphon is attached to the upper part of the hollow rod. ! 7. The signaling device according to claim 1, characterized in that the metal anode is made in the form of a rod. ! 8. The detector according to claim 1, characterized in that the outer casing is provided with two holes, one of which is located above the level of the upper air electrode, and the other is located in the lower part below the level of the metal electrode.

Description

The utility model relates to electrical engineering, specifically to electrochemical water level alarms and can be used on sea vessels and in river-sea mixed navigation vessels. The use of signaling the level of incoming sea water on ships contributes to the unsinkability of ships. To prevent ship accidents due to leakage of the outer skin, bottom cracks, holes, etc., the condition of the ship’s watertight parts is regularly checked, and when the ship is on the move, water measurements in bilges are performed every shift (Manual on the prevention of accidents and the struggle for survivability of ships USSR Fleet of Fishing Industry, p. 17, clause 2.3.8., and p. 29, cl. 2.8.7., Leningrad, “Transport”, Leningrad Department, 1983). Measurements are made by the test tubes through measuring tubes (Rules for the classification and construction of ships, vol. 2, p. 109, p. 10.4.3, Russian Maritime Register of Shipping, St. Petersburg, 2003). Of particular importance is the control of the flow of water above the maximum permissible (emergency) level. On ships equipped with an emergency warning system (APS), the emergency water level in bilge wells and shaft shafts tunnels should be monitored and recorded, for which purpose the level indicators for incoming water are intended (mentioned Rules, p.576, clause 4.7.3. and 4.7.4.). According to clause 7.10.2. of these Rules (p. 281),

Signaling devices shall be installed in each section of the vessel, separated by watertight bulkheads.

A known sensor for monitoring water leaks, comprising a housing of water-absorbing material with built-in perforated electrodes separated by a permeable dielectric gasket. The electrodes are connected to a power source and a control panel (RF patent 72859 U1, A62C 39/00 2007). When fresh, non-conductive water gets on the case, the latter works like a wick, picks up moisture, soda or salt dissolves and the water becomes conductive. Then moisture impregnates the gasket and turns it into an electrolyte carrier, the electric circuit between the electrodes closes and a signal is sent to the control device.

The disadvantage of this known is the complexity of the device of the detector due to the presence of an external power source, and the presence of a moisture-permeable gasket. Another disadvantage of the signaling device is its unreliability due to the possibility of transmitting false signals. Firstly, when dew occurs, as well as when swimming in a humid climate, condensate, falling on the sensor’s gypsum body, is absorbed by its pores and water, which has turned into an electrolyte, when passing through the walls of the body, fills the gasket, closing the electrical circuit, causing a false signal about the presence of water in its actual absence.

The closest in technical essence and the achieved technical result is a signaling device containing an external vertical casing in the form of a pipe and a sealed hollow rod coaxially mounted in it with level sensors located along the height of the hollow rod (RF patent 2284480 G01F 23/30, 2006).

The disadvantages of this detector are the design complexity (sealed cavity and container with magnetic fluid in the float, sectional measuring winding) and power from the mains.

The technical result of the utility model is to increase the reliability of the signaling device by simplifying its design and eliminating an external power source ..

The specified technical result is achieved by the fact that the electrochemical signaling device for incoming sea water contains an external vertical casing in the form of a pipe and a sealed hollow rod coaxially installed in it with level sensors located along the height of the rod, while gas diffusion air electrodes mounted in the level are taken the bottom and walls of the hollow rod, the cavity of the rod communicates with the air environment, the body is made of insulating material and contains metal at the bottom an electrode.

The presence of air electrodes and a metal electrode can significantly simplify the design of the signaling device by eliminating an external voltage source. The signal is generated by the signaling device itself, due to the occurrence of an EMF between the electrodes.

It is advisable that the air electrodes were located on the walls of the hollow rod with overlap. This allows you to continuously monitor the level of incoming water.

It is advisable that the metal electrode was made of aluminum alloy. The aluminum electrode in EMF mode is passivated and not consumed, which increases the life of the detector.

It is advisable that the air electrode mounted in the bottom of the hollow rod, was made flat or convex down.

This embodiment of the air electrode prevents the accumulation of bubbles on its surface, which due to the shielding of part of the area of the air electrode affect the output signal of the signaling device.

It is advisable that an air pipe with a siphon be attached to the upper part of the hollow rod. The presence of a siphon prevents water from entering the air cavity of the rod and disruption of the signaling device.

It is advisable that the metal anode be made in the form of a rod. This design of the electrode simplifies its mounting in the detector.

It is advisable that the outer casing be provided with two holes, one of which is located above the level of the upper air electrode, and the other is located in the lower part below the level of the metal electrode. This location of the holes provides a signal in the entire range of operability of the detector.

The analysis of the prior art showed that the claimed combination of essential features set forth in the utility model formula is unknown. This allows us to conclude that it meets the criterion of "novelty."

The essence of the utility model is illustrated by drawings and a description of the design and operation of the detector.

Figure 1 presents the device of the detector with the location of the air electrodes on the walls of the hollow rod,

Figure 2 shows a cross section of one of the possible signaling device 1 ¹ -1 ¹ ,

Figure 3 shows a convex air electrode mounted in the bottom of the air chamber,

Figure 4 shows a flat air electrode mounted in the bottom of the air chamber with an inclination,

Figure 5 shows the formation of signals depending on the level of incoming water,

Figure 6 shows the position when the indicator was completely under water.

The signaling device consists of 2 main parts made of dielectric material, for example, polyamide: a vertically mounted outer casing 1, with a bottom 2 and a wall 3 forming an inlet cavity 4, and a coaxially sealed air chamber 5 with air electrodes inserted into it 6, which are mounted in the walls 7 of the chamber 5 with gaps 8 in height, the gaps between the electrodes on one wall being blocked by electrodes on the other wall. This overlap 9 is appropriate to ensure the continuity of the signal transmitted by the detector. Alternatively, the electrodes may be located without overlapping gaps. Structurally, the air electrodes can be mounted in the air chamber in different ways: in a cylindrical chamber - with the electrodes in one vertical row, or on its opposite sides with a stepwise arrangement of the electrodes along the spiral generatrix; in the chamber in the form of a parallelepiped - with a stepwise arrangement of electrodes on 1-4 walls; with a triangular shape of the cross-section of the camera - on 1-3 walls. One flat air electrode 10 is installed in the bottom 11 of the air chamber 5. Option: the air electrode installed in the bottom 11 of the chamber 5 has a convex shape 12; another option: a flat electrode 13 is mounted in the bottom 11 of the chamber 5 with an inclination relative to the bottom 2 of the housing 1. To the upper closed part 14 of the air chamber 5 is connected a pipe 15 with a siphon 16. In the wall 3 of the housing 1 there is

a hole 17 at the bottom 2 and a hole 18 in the upper part of the housing above the level of the upper air electrode 19.

Inside the filling cavity 4 there is an anode-rod made of a special aluminum alloy 20. One of the possible ways of installing the rod is shown in the drawing: introducing it into the mounting holes 21 and 22 and fixing it with nuts 23 through gaskets 24. It should be noted that there can be different structural solutions of the installation and fixing the rod, which are not the subject of the application. For the same reason, and also because the shape of the aluminum anode does not play a role, the application for the installation of a flat anode is not given in the application. Wires - current leads 25 of the air electrodes 6 are assembled into a bundle 26, which is hermetically removed from the detector through the upper closed part 14 of the air chamber. The wire - the current output of the aluminum rod 27 is connected to the rod 20 outside the housing 1.

According to a utility model, the alarm device works as follows: water enters the alarm device through the lower hole 17, displacing air through the upper hole 18. When the level rises, sea water washes the outer surfaces of the air electrodes and those electrodes to which the water has risen immediately generate EMF. The table shows the discreteness of the signals depending on the water level shown in figure 5.

Water level number in the indicator The numbers of water levels that the signaling device transmits a signal about 1.1 no signal 1.2 2.1 1.3 2.1, 2.2 1.4 2.1, 2.2, 2.3 1.5 2.1, 2.2, 2.3, 2.4 1.6 2.1, 2.2, 2.3, 2.4, 2.5

Thus, all air electrodes that are washed by seawater entering the detector work.

The smaller the height of the electrodes, the smaller the discrete measurement interval and the error in the absolute measurement of the water level.

With a further supply of water to level 28, when the detector is completely under water, it continues to generate EMF. continuing to signal an emergency. At the same time, siphon 16 of pipe 15 prevents the penetration of water into the air cavity of the detector: the water level 29 in the neck 30 of the siphon 16 is determined by the static pressure of the water in it.

When the water level drops, it immediately drains from the signaling device and the air electrodes, which have stopped washing the water, cease to produce EMF.

Over time, when in seawater, an aluminum hydroxide layer may appear on the surface of the anode. Periodically, in accordance with the operating instructions of the signaling device, it is advisable to replace the anode with a new one, which is included in the set of each signaling device.

Due to the fact that the hydrophobic surface of a horizontally located flat air electrode installed in the bottom of the air chamber can be partially shielded by air bubbles from wetting with sea water, washing off air bubbles entering the detector with sea water is provided when one of the inventive versions of convex and inclined electrodes is used.

The above information confirms that the claimed detector can be implemented in practice, which confirms the compliance of the claims with the condition "industrial applicability".

Claims (8)

1. An electrochemical signaling device for incoming sea water, comprising an outer vertical casing in the form of a pipe and a sealed hollow rod coaxially installed in it with level sensors located along the height of the rod, characterized in that gas diffusion air electrodes mounted in the bottom and walls are taken as level sensors hollow rod, the cavity of the rod communicates with the air environment, the housing is made of insulating material and contains a metal electrode in the lower part. 2. The signaling device of claim 1, characterized in that the air electrodes are located on the walls of the hollow rod with overlap. 3. The detector according to claim 1, characterized in that the metal electrode is made of aluminum alloy. 4. The detector according to claim 1, characterized in that the air electrode mounted in the bottom of the hollow rod is made flat. 5. The detector according to claim 1, characterized in that the air electrode mounted in the bottom of the hollow rod is made convex down. 6. The signaling device according to claim 1, characterized in that an air pipe with a siphon is attached to the upper part of the hollow rod. 7. The signaling device according to claim 1, characterized in that the metal anode is made in the form of a rod. 8. The detector according to claim 1, characterized in that the outer casing is provided with two holes, one of which is located above the level of the upper air electrode, and the other is located in the lower part below the level of the metal electrode.