UA82146C2 - Ventilation device for accumulator - Google Patents

Abstract

A ventilation device consists of a camera and openings, an explosion-proof element in the form of a disk made from acid-proof material and combined reflector and electrolyte aerosols trap made as a labyrinth of cylindrical form. The labyrinth has at least two camera of labyrinth arranged one above another and formed with narrow parts of labyrinth separated by two wide parts of labyrinths close adjacent to a ventilation device body. On wide parts of labyrinth it is made two cuts formed with the ventilation device body two gaps for gas passing, cuts at adjacent parts, which restrict one labyrinth camera located π/2 angle one relatively another, maximum wide of gap formed with cuts is 0,1-0,3 part of wide labyrinth side radius. Correlation of narrow and wide parts radii of labyrinth is within limits of 2-4, correlation of heights of narrow and wide parts of labyrinth is within limits of 0,5-2,0.

Description

Description of the invention

The invention relates to the electrotechnical industry, namely, to the production of accumulators and 2 accumulator batteries (products).

An important structural part of accumulators and rechargeable batteries is a ventilation device that ensures the release of gases that are formed during the operation of the products, the retention of aerosols and drops of electrolyte, and also protects the product from possible dust, electric sparks or flames entering its internal volume.

A ventilation device is known that connects on one side with the internal volume of the battery, on the opposite side - with the external environment, which has a housing with a camera and holes, a reflector and a trap for electrolyte aerosols (A.s. Mo1017133 USSR, 1981). The device is made in the form of a filler plug.

The reflector is the lower part of the cork body with a narrow opening for the passage of gases. The reflector allows you to return drops and splashes of the electrolyte back into the volume of the product. Electrolyte aerosol catcher is made as a filler made of granular material insoluble in the electrolyte. The granular material of the catcher traps 12 aerosol fractions, preventing their release into the environment. The disadvantage of such a device is the untechnological nature of its assembly, as well as the risk of explosion. In the design of the ventilation device, there is no element that would protect the internal volume of the product from detonation due to possible electric sparks arising in the external space, for example, at the terminals of the battery, and capable of causing an explosion of a mixture of gases in the internal volume that are released when product operation.

A ventilation device is known that communicates on one side with the internal volume of the battery, on the opposite side - with the external environment, which has a housing with a camera and holes, an electrolyte aerosol trap and an explosion-proof element (A.s. Mo1238654 USSR, 19811.

The device is made in the form of a filler plug. The trap of electrolyte aerosols is a cork body with a rod with annular protrusions inserted inside. Due to the turbulence of the flow of gases in the gaps between the plug body and the rod, the gases are cooled and the electrolyte aerosols condense, and then the droplets return to the internal volume of the battery. The explosion-proof element is made in the form of a cap made of porous material. A possible external spark or flame is extinguished in the pores of the cap.

The disadvantage of the device is its low reliability. The absence of a reflector in the design leads to the fact that splashes of electrolyte penetrate into the plug body, and the liquid fills the internal volume intended for co-condensation of electrolyte aerosols. As a result, the efficiency of aerosol capture decreases, and part of the aerosol fractions condenses on the porous cap, clogging its pores. This leads to the blowing of electrolyte drops into the external environment. In addition, the pores of the cap are not protected from external dust and can (87) quickly become clogged, which will bring the device and the entire product out of order.

The closest technical solution that we have taken is a ventilation device that communicates on one side with the internal volume of the battery or batteries, on the opposite side - with the external environment, which has a housing with a camera and holes, a reflector, an electrolyte aerosol catcher and an element explosion protection (Patent

Mo2113746 of the Russian Federation, 1998, Bull. Mo17)|. The body is a removable cap and the adjacent part of the battery cover, in which there is a camera. The reflector and the trap of electrolyte aerosols are combined in the design of the condensing disc, which creates an arc-shaped gap with the walls of the chamber for the passage of gases. The condensing disc prevents 70 the direct impact of electrolyte splashes on the explosion-proof element, acting as a reflector, and also serves to condense electrolyte aerosols. The explosion-proof element is made in the form of a disk made of porous acid-resistant material. A possible external spark or flame is extinguished in the pores of the disk. The advantage of the device of the closest analogue (hereinafter NA) is its ease of assembly. In the NA device, the pores of the explosion-proof element are more or less protected from the ingress of external dust. The disadvantage of the device is its low reliability. The design of the electrolyte aerosol catcher in the form of a conventional disc is inefficient. It does not provide sufficient turbulence and cooling of the gas flow, as a result of which the condensing disc passes part of the aerosol fractions that condense on the porous disc, clogging its pores, preventing the free release of gases. This leads to the blowing of electrolyte drops into the external environment. 20 The invention is based on the task of increasing the reliability of the ventilation device by improving the protection of the explosion-proof element from electrolyte condensate, by increasing the turbulence of the flow of gases formed during the operation of the product.

The task is solved by the fact that in the ventilation device, which communicates on one side with the internal volume of the battery or batteries, on the opposite side - with the external environment, which has a 25 housing with a camera and holes, a reflector, an electrolyte aerosol catcher and an element explosion protection, and the reflector and electrolyte aerosol catcher are combined in a single design, the explosion safety element is made in the form of a disk of porous acid-resistant material, according to the invention, the design of the combined reflector and electrolyte aerosol catcher is a labyrinth of a cylindrical shape, which has at least two labyrinth chambers, located one above the other and formed by narrow places of the labyrinth, separated by at least two wide 60 places of the labyrinth, which are close to the body of the ventilation device, two cuts are made at the wide places of the labyrinth, which create two gaps with the body of the ventilation device for the passage of gases, and the cuts on the neighboring streets wide places that limit one chamber of the labyrinth are located at an angle to each other P/2, the maximum width of the gaps formed by the sections is 0.1-0.3 part of the radius of the wide places of the labyrinth, the ratio of the radii of the wide and narrow places of the labyrinth is in the range of 2-4, because the ratio of the heights of the wide and narrow places of the labyrinth is in the range of 0.5-2.0.

The cylindrical labyrinth placed in the housing of the ventilation device effectively acts as a reflector of splashes of electrolyte. Electrolyte splashes are reflected by the two lower wide places of the labyrinth, which are close to the housing of the ventilation device. The location, number and width of the gaps are selected empirically so that they do not reduce the reflective capacity of the labyrinth. If the maximum width of the gaps exceeds 0.3 parts of the radius of the wide place of the labyrinth, and the number of gaps exceeds two, then the reflective ability of the labyrinth is reduced, as a result of which splashes of electrolyte can penetrate up to the element of explosion protection, clogging its pores. This happens because a direct path is opened from the internal volume of the battery to the explosion-proof element. The same thing happens if the angle of the mutual location of the gaps on the adjacent 7/0 wide places of the labyrinth differs from l/2. If the maximum width of the gaps is less than 0.1 parts of the radius of the wide part of the labyrinth, and the number of gaps is less than two, it becomes difficult for the condensate to flow back into the internal volume of the battery.

The cylindrical labyrinth effectively acts as a trap for electrolyte aerosols, since the aerosol fractions are forced to pass a winding path along the cylindrical labyrinth from the internal volume of the battery to 7/5 of the explosion-proof element and exit to the outside environment. Gases and aerosols, passing along a winding path through the gaps and chambers of the labyrinth, greatly change the speed and direction of the flow, since the gas velocity is maximum in the gaps, and minimum in the chambers of the labyrinth. Such pulsation of the flow leads to its turbulence and cooling. As a result, aerosols condense and settle on the walls of the labyrinth and the housing of the ventilation device in the form of drops, and through the gaps the drops flow back into the internal space of the battery. The number of chambers of the labyrinth, the number of wide places of the labyrinth with gaps, the ratio of the radii of the wide and narrow places of the labyrinth, the ratio of the heights of the wide and narrow places of the labyrinth are selected empirically to ensure active turbulence of the gas flow. If the chambers of the labyrinth and the wide places of the labyrinth will be less than two, or the heights of the wide and narrow places of the labyrinth will be significantly different (the ratio of the heights of the wide and narrow places of the labyrinth will exceed the limits of 0.5-2), or the ratio of the radii of the wide and narrow places of the labyrinth will be less than two , then sufficient gas flow turbulence and aerosol condensation will not be ensured.

If the ratio of the radii of the wide and narrow places of the labyrinth is more than four, then it is unacceptable i) the strength of the labyrinth itself will decrease, which may lead to its damage when assembling the ventilation device.

The explosion-proof element in the claimed invention, as well as in NA, is made in the form of a disc made of porous acid-resistant material. A possible external spark or flame is extinguished in the pores of the disk.

Figure 1 shows two projections of the ventilation device. h

Fig. 2 shows a general view of a cylindrical labyrinth, which combines the functions of a reflector and - a trap of electrolyte aerosols, and also shows a projection of a cylindrical labyrinth with an indication of the required dimensions. with

The ventilation device is made in the form of a plug for the filling hole of a battery or a battery with a battery, and has a body 1 with a chamber 2, with holes 3, 4 for the entry and exit of gas and aerosol fractions. A cylindrical labyrinth 5 is tightly inserted into the large hole located at the bottom of the plug, through which gas and aerosol fractions enter directly from the internal volume of the battery. An explosion-proof element - disk 6 - is firmly inserted inside the plug housing. The procedure for assembling the ventilation device is as follows. "

First, a disc 6 is tightly inserted into the cork body 1 under the very top of the cork, and then the cylindrical labyrinth 5 is tightly inserted -o s. The cylindrical labyrinth 5 has chambers 7 of the labyrinth, located one above the other, and the number of which in this example is two, but in the general case - at least two. The number of cameras 7 is limited "" only by the size of the cork. Chambers 7 are formed by narrow places of the labyrinth 5 and separated by wide places 8 of the labyrinth, the number of which in this example is two, but in the general case - at least two. When installing the labyrinth 5 in the housing 1, the wide places 8 of the labyrinth are closely adjacent to the housing 1. The ratio of the radii

Go! wide K and narrow g places of the labyrinth is K/y-2-4. The ratio of the heights of wide H and narrow and places of the labyrinth is H/n-0.5-2.0. Two cuts 9 are made on wide places 8. These cuts 9 form gaps 10 ko for the passage of gases and aerosols. The maximum width a of the gaps formed by the slices 9 is 0.1-0.3 part - from the radius K of the wide places of the labyrinth 5. The location of the slices 9, which limit one chamber of the labyrinth, is perpendicular to each other (at an angle l/2). The construction of the cylindrical labyrinth 5 may have some optional details, but they do not affect the general idea. Thus, in this example, we have an opening 11 for the passage of gases and b aerosols and a protrusion 12 located on the upper extension 13 of the labyrinth 5 (the radius of the upper extension 13 is equal to K - the radius of the wide places 8 of the labyrinth). their purpose is to direct gases and aerosols through a rubber valve, which, in principle, can be installed on the protrusion 12. In addition, in this example, we have the base 14 of the labyrinth 5, which serves for the convenience of installing the labyrinth 5 in the housing 1 or removing it from the housing.

Now let's describe the operation of the ventilation device - the plug of the filling hole. In the process of charging and operation, gases (oxygen and hydrogen) and electrolyte aerosols are released from the products, and the gases must be removed to the outside environment. In addition, splashes of electrolyte may form in the internal volume of the batteries. At the same time, in in connection with safety and environmental protection requirements, aerosols must be deposited back into the internal volume of the battery. In the path of splashes of electrolyte, gases and aerosol fractions there is a plug of the filling hole with a cylindrical labyrinth 5. The first function of the labyrinth 5 is a splash deflector and drops of electrolyte. Electrolyte splashes are reflected by the two lower wide places 8 of the labyrinth 5, adjacent closely to the housing 1 of the ventilation device. Gases enter the chamber 2, passing through the cylindrical labyrinth 5 of this plug. Aerosols are retained on the walls of the labyrinth 5 and 65 flow back into the internal environment Thus, the cylinder labyrinth 5 performs a second function - the function of an aerosol trap e electrolyte The proposed design allows for another possible way for gases to escape from batteries, which does not affect the overall design.

The gases can pass through the cylindrical labyrinths of other plugs, where they are freed from the electrolyte aerosols that condense in the labyrinth, and then the gases through the central gas outlet channel (not shown in the figure) and hole C enter chamber 2. After chamber 2, the gases pass through the porous disk 6. Here, in the pores of disk 6, extinguishing of possible combustion products occurs in the event of sparks or flames in the external environment.

Thus, the porous disk 6 allows you to ensure the explosion safety of the product.

Having passed the disk b, the gases are discharged into the external environment through a narrow hole 4. The small diameter of the hole 4, as in the case of the prototype, provides more or less reliable protection against clogging of the pores of the disk 6 with dust from the external environment. 70 Laboratory tests in conditions of cycling and recharging according to the European standard (EM 503421), as well as more than two years of product operation experience confirm the effectiveness of the declared ventilation device.

The pores of the explosion-proof element are not clogged with electrolyte or dust, drops of electrolyte do not penetrate into the external environment.

Claims (1)

19 Formulation of the invention A ventilation device that communicates on one side with the internal volume of the battery or batteries, on the opposite side - with the external environment and has a housing with a camera and holes, a reflector, an electrolyte aerosol catcher and an explosion-proof element, and a reflector and an aerosol catcher of electrolyte are combined in a single structure, the explosion-proof element is made in the form of a disk of porous acid-resistant material, which is distinguished by the fact that the design of the combined reflector and trap of electrolyte aerosols is a labyrinth of a cylindrical shape, which has at least two chambers of the labyrinth, located one above the other and formed by narrow places of the labyrinth, separated by at least two wide places of the labyrinth, which are adjacent to the housing of the ventilation device, two cuts are made in the wide places of the labyrinth, which form two gaps with the housing of the ventilation device for the passage of gases, and the cuts in the adjacent wide places that vol form one chamber of the labyrinth, located at an angle to each other P/2, the maximum width of the gaps formed by the sections is 0.1-0.3 part of the radius of the wide places of the labyrinth, the ratio of the radii of the wide and narrow places of the labyrinth is within 2- 4, the ratio of the heights of the wide and narrow places of the labyrinth is in the range of 0.5-2. "-- with Zo so - and? so ko - their 50 (42) ko 60 b5