ITVI20130298A1 - COVER FOR ELECTRIC ACCUMULATOR WITH GAS BREATHER CHAMBER - Google Patents

Description

COVER FOR ELECTRIC ACCUMULATOR WITH GAS VENT CHAMBER.

DESCRIPTION

The present invention relates to a lid for an electric accumulator provided with a gas vent chamber and used in motor vehicles.

It is known that accumulators, in particular lead-acid electric accumulators, are essentially formed by a series of cells where positive / negative plates are inserted immersed in an electrolyte, generally consisting of an aqueous solution of sulfuric acid. The plates are electrically connected to each other giving rise to chemical reaction processes with the electrolyte, in such a way as to generate an electric current that is collected at the accumulator poles.

During its technical life, the accumulator is subject to charging and discharging processes during which the water of the electrolytic solution tends to dissociate, developing hydrogen.

It is also known that hydrogen is highly flammable and it has been shown that the hydrogen-air mixture becomes flammable when the hydrogen contained in this mixture varies from a minimum percentage of 4% to a maximum percentage of 75%.

Under normal operating conditions of the accumulator it often happens that the hydrogen concentration is within the flammability limits, that is, it is higher than 4%.

For this reason, taking advantage of the high volatility of hydrogen, gas discharge channels are used, so that the hydrogen is removed from the accumulator and dispersed in the air.

Another problem is the fact that, given the flammability of hydrogen, any sparks that may be created could ignite flames that could easily spread from the outside to the inside of the accumulator.

Any propagation of flames inside the accumulator would cause the accumulator to burst.

For this reason, many types of accumulators are equipped with flameproof pads (flame arrestor) which are placed inside the hydrogen exhaust ducts in order to prevent the flame from flowing back into the accumulator.

The explosion-proof pads are equipped with micro-holes, which are distributed according to a labyrinthine path that constitutes an insurmountable barrier to the propagation of the flame and therefore prevents its spread within the accumulator.

A further problem is the fact that, during the operation of the accumulator, the gas discharge holes also allow part of the electrolyte to escape.

Any electrolyte leakage from the drain holes can allow it to reach the explosion-proof pads, clogging them and seriously compromising their operation, in particular their task of preventing the flames from flowing back into the accumulator.

To try to solve this drawback, it was decided to create a chamber on the accumulator cover equipped with a gas vent hole and separated from a further adjacent chamber, provided with a housing seat for the explosion-proof pad, by means of dividers.

These dividing baffles are provided with openings offset from each other in such a way as to create a tortuous path for the electrolyte that comes out of the drain hole and flows towards the explosion-proof pad, clogging it.

This tortuous path, however, is not always sufficient to prevent the electrolyte from reaching the explosion-proof pad.

For this reason it was decided to create an adduction channel around the gas discharge hole in such a way that it would facilitate the return of the electrolyte inside the discharge hole when the accumulator cools down in the rest phase.

However, the conformation of this adduction channel is not such as to allow the electrolyte in the drain hole when the electrolyte head that has spread inside the chamber where the drain hole is present is low.

The present invention intends to eliminate the aforementioned drawback.

In particular, the main object of the present invention is to provide a lid for accumulators provided with one or more discharge holes for the gas in which it is possible, during the resting phase of the accumulator, to re-enter as much of the electrolyte as possible. .

A further purpose of the present invention is to create a lid for accumulators equipped with discharge channels and an adduction channel configured in such a way as to be able to bring in the leaked electrolyte even in the event that the leaked electrolyte head is low.

The above objects are achieved by the present invention relating to a lid for electric accumulators whose fundamental characteristics are in accordance with the teachings of the main claim.

Further detailed features of the invention are in accordance with the dependent claims.

Advantageously, the lid for accumulators according to the present invention allows most of the electrolyte leaking from the drain hole to re-enter the hole.

Equally advantageously, the lid for accumulators according to the present invention has an adduction channel in communication with the gas discharge hole, having a mainly longitudinal development which facilitates the suction of the electrolyte present in the channel itself.

Equally advantageously, the lid for accumulators according to the present invention has an adduction duct configured in such a way as to allow the return of the leaked electrolyte into the chamber of the drain hole even when its head is low.

The aforementioned purposes and the aforementioned advantages will be better highlighted during the description of a preferred embodiment of the invention which will be given below by way of indication but not limitation, with reference to the attached drawing tables where:

- fig. 1 represents a partially exploded isometric view of a lid for accumulators according to the invention;

- fig. 1a shows a detail of fig. 1;

- fig. 2 shows a side view of the lid of fig. 1;

- fig. 3 represents an axonometric view of a further detail of fig. 1;

- fig. 4 represents an axonometric view of the lid of fig. 1 coupled to a container of an electric accumulator.

With reference to figs. 1 and 4, a lid is shown, indicated as a whole with 1, which comprises:

- a shaped body 2 adapted to couple with the container 3 of an accumulator A and provided with a plurality of holes 5 spaced apart for the introduction of an electrolyte;

- a drain hole 4 obtained laterally in the shaped body 2 to allow the gas produced inside the container to escape - an adduction channel in communication with the drain hole 4. With reference to fig. 1, the axis (not shown in the figure) of the drain hole lies on a development plane parallel to that of the lid 1, while the adduction channel lies on a development plane substantially orthogonal to that of the lid 1.

Basically, on the basis of what has just been said, the discharge hole 4 and the adduction channel lie on two planes substantially orthogonal to each other.

In accordance with the present invention, the supply channel has a prevalently longitudinal development and is provided with two supply channels, 6 and 7 respectively, one of which is in communication with the gas discharge hole 4 and the other is arranged near the bottom of the adduction channel.

Again with reference to fig. 1, the cover 1 is provided with further holes 21, 22 for the insertion of the poles in the accumulator A.

As can be seen in the detail of fig. 1a, the adduction channel has a substantially vertical development and its longitudinal axis X is orthogonal to the axes of symmetry, respectively Y and Z1, of the two adduction ways 6 and 7.

In particular, the supply route 7 is substantially horizontal and parallel to the bottom wall 20 of the first chamber 10.

With reference to figs. 2 and 3, the adduction channel is formed by two portions: a first portion 5a obtained in the shaped body 2 of the cover 1 and a second portion 5b obtained in a plate 8, external to the shaped body 2 and able to couple to it.

The sealing coupling of the conjugable profiles of the first portion 5a and the second portion 5b of the adduction channels, when the plate 8 is coupled to the cover 1, forms the entire adduction channel.

The resulting adduction channel has a substantially L-shaped configuration which comprises a first substantially vertical section and a second section, connected to the first and substantially parallel to the bottom wall 20 of the first chamber 10.

As can be seen in the detail of figs. 1, 1a and 2, the hole 4 and the first portion 5a of the adduction channel belong to a single shaped protrusion that starts from the surface 9 of a first chamber 10.

With reference to figs. 1a and 2, adjacent to the first chamber 10 there is a second chamber 11 provided with a housing seat 12 for an explosion-proof pad (not shown in the figures).

With reference to fig. 2, the first and second chambers, 10 and 11 respectively, are separated by two dividing baffles 13 spaced apart and provided with openings 14a, 14b suitable for placing the chambers 10 and 11 in communication with each other.

Advantageously and in accordance with the known art, these openings 14a, 14b are offset from each other so as to make difficult the path of the electrolyte that comes out of the drain hole 4 during the operation of the accumulator A.

With reference to the detail of fig. 3, it shows a detail of the plate 8.

It shows the second portion 5b of the adduction channel, suitable for coupling with the first portion 5a to define the entire adduction channel.

This second portion 5b comprises a substantially L-shaped part with two supply routes, respectively 6 'and T.

A rounded part 5c is connected to the supply way 6 'which is suitable for coupling with the drain hole 4, as will be better illustrated below.

The second portion 5b of the adduction channel and the rounded part 5c are delimited by a single border 15.

The plate 8 has, again with reference to fig. 3, also a cylindrical protrusion 16 adapted to couple with the housing seat 12 of the explosion-proof pad, according to the known art.

The cylindrical protrusion 16 and the skirt 15 are separated by two dividing edges 17 which are spaced apart and parallel to each other,

The plate 8 is finally provided with a plurality of engagement teeth 18 spaced apart which, advantageously, favor the stable coupling of the plate 8 with the cover 1.

Operationally and with reference to Figures 1 to 3, the user, after having filled the accumulator A with an electrolyte by inserting it through the holes 5, couples the plate 8 to the cover 1 in such a way that the surfaces 19 of the respective teeth 18 enter in contact with the internal walls 20 of the first chamber 10 and of the second chamber 11.

The contact by ultrasonic welding between the surfaces 19 and the internal walls 20 causes the stable coupling of the plate 8 with the cover 1.

With the coupling of the plate 8 to the cover 1, the profile of the rounded part 5c, conjugated to that of the drain hole 4, is coupled to the latter.

With reference to fig. 2, during the operation of accumulator A the gases come out from the drain hole 4 and part of the electrolyte also comes out.

When the operation of accumulator A is interrupted, it begins to cool. While the accumulator A cools, its internal temperature also decreases and, consequently, its internal pressure also decreases.

The decrease in pressure in accumulator A creates a depression, with respect to the external atmospheric pressure, which allows the electrolyte leaked into the first chamber 10 to re-enter the drain hole 4.

Since the adduction route 7 is at a height H with respect to the bottom wall 20 of the first chamber 10, the electrolyte which is located above the head defined by the height H can re-enter the hole 4 following the path defined by the adduction canal.

Furthermore, with reference to fig. 2, it should be noted that the opening 14a is opposite to the supply route 7 with respect to the horizontal axis Z2 of the first chamber 10. This means that the electrolyte, in order to pass through the opening 14a, must overcome a difference in height significant with respect to the height level H.

Advantageously, the fact that the adduction channel has a predominantly vertical development facilitates the suction of the electrolyte present in the channel towards the drain hole.

Still advantageously, the fact that the inlet path located near the bottom of the inlet channel is oriented towards the second chamber and is located at a relatively close height with respect to the bottom wall of the first chamber, facilitates the aspiration of a quantity of electrolyte which is higher than that which is sucked in accumulators of known type.

In the present description, reference has been made to a single drain hole, but it is clear that the cover for accumulators according to the invention, according to executive variants not illustrated, can also have two or more drain holes spaced apart and having the same gas expulsion function.

Based on what has been described so far, it is understood that the lid according to the invention achieves the intended purposes.

In the executive phase, changes can be made to the lid according to the invention which, if they fall within the scope of the following claims, must be considered protected by this patent.

Claims (10)

CLAIMS 1) Cover (1) for electric accumulators of the type comprising: - a shaped body (2) adapted to couple with the container (3) of the accumulator (A), said shaped body (2) being provided with one or more holes (5) spaced apart for the introduction of an electrolyte in said container (3); - one or more discharge holes (4) obtained in said shaped body (2) and adapted to allow the escape of the gas produced in said container (3); - one or more supply channels, each of which is in communication with a respective drain hole (4), each discharge hole (4) being provided with a longitudinal axis lying on a plane substantially parallel to the development plane of said cover (1) and each inlet channel being provided with a longitudinal axis (X) lying on a plane substantially orthogonal to the development plane of said cover (1), characterized by the fact that each adduction channel has a prevalently longitudinal development and is provided with two adduction ways (6, 6 ', 7, 7') spaced apart, one of which ( 6, 6 ') is in communication with said discharge hole (4) and the other (7, 7') is arranged near the bottom of said adduction channel. 2) Cover (1) according to claim 1, characterized in that each supply channel comprises a first portion (5a), obtained in said shaped body (2) of said cover (1), and a second portion (5b) obtained in a plate (8) external to said shaped body (2), said first (5a) and said second portion (5b) having profiles that can be conjugated and coupled together in a sealed manner. 3) Cover (1) according to claim 1, characterized in that both the first portions of said supply ways (6, 7) have an axis of symmetry (Y, Z1) substantially orthogonal to the longitudinal axis (X) of said first portion of said adduction channel. 4) Cover (1) according to any one of the preceding claims, characterized in that said first portion of said inlet channel and said discharge hole (4) are arranged in a first chamber (10) adjacent to a second chamber (11) . 5) Lid (1) according to claim 4, characterized in that said first (10) and said second chamber (11) are separated by a plurality of dividing baffles (13) provided with openings (14a, 14b) offset from each other and able to put in communication said first chamber (10) with said second chamber (11). 6) Cover (1) according to claim 5, characterized by the fact that one of said openings (14a) which communicates with said first chamber (10) and the supply way (7) arranged in proximity to the bottom of said first portion of said adduction channel are opposite with respect to the horizontal axis (Z2) of said first chamber (10). 7) Cover (1) according to any one of the preceding claims, characterized in that said inlet way (7) arranged near the bottom of said inlet channel is oriented towards said second chamber (11). 8) Cover (1) according to any one of the preceding claims, characterized in that each supply channel has a configuration which comprises a first section substantially orthogonal to the bottom wall of said first chamber (10) and a second section, communicating with said first section, substantially parallel to the bottom wall (20) of said first chamber (10). 9) Cover (1) according to any one of the preceding claims, characterized by the fact that the inlet way (7) arranged near the bottom of said first portion (5a) of said inlet channel has an axis of symmetry (Z1) substantially parallel to the bottom wall (20) of said first chamber (10). 10) Cover (1) according to any one of the preceding claims, characterized in that each supply channel has a substantially L-shaped configuration. By assignment.