SE447180B - KERL FOR ELECTRICAL CHEMISTRY CELL MANUFACTURED IN ONE PIECE OF PLASTIC MATERIAL - Google Patents

Description

447 180 2 .I Such a vessel for an electrochemical cell has a sufficiently robust construction.

However, a cell with this vessel has a rather low specific energy (Wh / kg), which considerably increases the weight of an accumulator battery built up by the cells in the metal vessels and, consequently, the weight of the machine in which it is used.

In addition, a metal vessel for an electrochemical cell is labor intensive.

The above-mentioned disadvantages are eliminated in vessels for electrochemical cells which are made of plastic material. Plastic vessels are made of heated material, and therefore a cooling of a finished product causes internal stresses, the value of which can exceed the strength of the vessel. At the points of sharp transition from one plane to another, ie at the strips of the vessel, stress concentrations occur which affect the strength of the vessel. To reduce the concentration of stress in vessels for electrochemical cells, the strips are made rounded.

Plastic vessels for electrochemical cells can be manufactured in two ways: by casting or by extrusion by blow molding.

Cast vessels usually consist of two parts, a body and a lid which are welded together after the electrochemical cell has been assembled. The mechanical strength of molded plastic vessels is achieved by making the vessel walls of specified thickness. however, the increase in wall thickness causes an increase in material consumption and consequently affects the specific energy of the accumulator cells and reduces the internal usable volume of the vessel, while on the other hand the overall dimensions of the vessel remain the same.

In addition, the equipment used for the manufacture of cast vessels is complex and expensive.

Therefore, one-piece vessels made by extrusion blow molding have now found widespread use.

These vessels should have walls of uniform thickness, i.e. the thickness and consequently the stiffness of all the walls should be the same. A uniform thickness of the transition from one wall to another is achieved by rounding the strips. With uniform thickness of all the walls of a vessel in one piece, stress concentrations are not produced which affect the strength of the vessel.

It is further known that vessels for an electrochemical cell, made of a plastic material in one piece with walls of uniform 3,447,180 in thickness and shaped like a rectangular parallelepiped with rounded strips, complete co-pole nozzle and a filling nozzle which are arranged on the top wall of the vessel (American U.S. Pat. No. 3,281,283).

This vessel has thin walls, which can not give them sufficient strength, when used for high-capacity electrochemical cells.

This disadvantage is eliminated by a known vessel for an electrochemical cell, which is the prototype of the present invention and is made of a one-piece plastic material with walls of uniform thickness and shaped like a rectangular parallelepiped with rounded strips. The vessel is supplemented with outer rectangular stiffening strips on its long sides and the pole socket filling nozzle on the top wall ("Sbornik robot po khimicheskim istochnikam toka" / Transactions on Electric Cells /, Leningrad, 1975, part 10, page 173).

The construction of such a vessel for an electrochemical cell shows low rigidity for the rounded strips, which reduces the strength of the vessel.

In addition, the top and bottom walls of the vessel, which constitute the load-bearing means of the structure and absorb the highest loads when the vessel is in service, offer sufficient rigidity, which affects the strength of the vessel for an electric cell and, consequently, the reliability of the vessel as a whole.

In a battery built up of accumulator cells with the above-mentioned vessels, abnormal temperature conditions are obtained for the work of the cells, since there are no air gaps between the cells for external cooling of the same, which impairs the operational reliability of the cells as a whole.

The main object of the present invention is to provide a vessel for an electrochemical cell in which the strips and the top and bottom wall should be manufactured so that they contribute to the rigidity of the vessel and consequently to increase their pour strength, thus the reliability of the vessel as a whole. improved.

This object is achieved with the vessel according to the present invention, which is characterized in that the vertical strips protrude from the side walls of the vessel, that the lower horizontal strips arranged along the length of the vessel project from the bottom wall of the vessel, all strips being made with boreholes to the walls from which they project, which boreholes are made with radii of at least 447 180 4 equal to the maximum distance from the surface of the strip to the wall of the vessel and with a ratio of the maximum maximum distance from the surface of the strip to the vessel wall and the width of the strips to 0.3, and that the vessel is further provided with at least two stiffening strips arranged along the width of the vessel and with a ratio between the height of the stiffening strip and the width of at least 1, one stiffening strip being made on the bottom wall, while the other the stiffening strip is made on the top wall and extends through the pole nozzle.

The vertical strips and the lower horizontal strips, which are arranged along the length of the vessel so that they protrude from the walls of the vessel provide an increased rigidity of the arranged strips, since the protruding strips act as stiffening strips and consequently improve the strength of the vessel as a whole. .

The vertical and lower horizontal strips, which protrude from the walls, also make it possible to create an air gap between the accumulator cells when they are assembled into a battery, which in turn improves the temperature conditions for the battery cells to work in the battery and, consequently, increases operational reliability. in the accumulator cell as a whole.

The strips, which are arranged along the length of the vessel so that they protrude from the bottom wall, enable a maximum reduction of the surface which is subjected to shock stresses and, consequently, an increase of the strength of the vessel.

The hollow springs arranged between the projecting strips at the walls with radii which are at least equal to the maximum distance from the strip surface to the vessel wall, provide a smooth transition from the strips to the walls, which prevents concentration of internal stresses to the transition.

As the ratio between the maximum distance of the strip surface from the vessel wall and the width of this surface is less than 0.05, the transition between the strip and the wall becomes too smooth, which does not give the vessel the required rigidity.

When the ratio between the maximum distance of the strip surface from the vessel wall and the width of this surface is greater than 0.30, the strips can be incorporated with the longitudinal wall of the vessel, ie the wall thickness will double, which will result in non-uniform wall thickness of the vessel as a whole and, thus, affect its strength. s 447 180 The stiffening strips on the bottom and top wall, which constitute the load-bearing means of the vessel which absorb the highest loads, make it possible to increase the stiffness and consequently the strength of the vessel as a whole.

When the ratio between the height and width of the stiffening strip is less than 1, this strip loses its stiffening capacity and it becomes possible to give the strip the required shape.

By making the stiffening strip on the top wall such that it extends through the pole pieces, a rigid connection is obtained between them, the rigidity of the attachment point for the electrical assembly is increased and the operational reliability of the vessel is improved.

According to one of the embodiments of the vessel for an electrochemical cell, the height of the stiffening strip on the bottom wall of the vessel does not exceed the maximum distance from the surfaces of the lower horizontal strips to the bottom wall of the vessel.

By making the stiffening strips on the bottom wall of the vessel with a height which does not exceed the maximum distance from the surfaces of the lower horizontal strips to the bottom wall of the vessel, the required stability of the vessel is achieved.

According to another embodiment of the vessel for an electrochemical cell, the height of the stiffening strip on the top wall of the vessel does not exceed the height of the pole pieces.

By making the stiffening strips on the top wall of the vessel with a height which does not exceed the height of the pole pieces, a simpler assembly of the accumulator cells into a battery is obtained.

The invention is described in more detail below with reference to the accompanying drawing, in which Fig. 1 shows a perspective view of a vessel for an electrochemical cell according to the present invention, and Fig. 2 shows a perspective view of a part of the vessel according to the invention.

The vessel for an electrochemical cell according to the invention is made of one-piece plastic material with walls of uniform thickness by inflating with air a hot substance around an assembly of different electrodes separated by a separator (not shown in the drawing) with further shaping the vessel into a mold.

The vessel for an electric cell is shaped like a rectangular parallelepiped with side walls 1, 2 Xfig. 1, 2), a bottom wall 3 (fig. 2), a top wall 4 (fig. 1) and rounding strips 5, 6, 7, 8, 9, more specifically: 447 180 6 J - vertical strips 5 between the side walls 1, 2; - lower horizontal strips 6 (fig. 2) between the side walls 1 and the bottom wall 3, arranged along the length of the vessel; - lower horizontal strips 7 (fig. 1, 2) between the side walls 2 and the bottom wall 3, arranged along the width of the vessel; - upper horizontal strips 8 (Fig. 1) between the side walls 1 and the top wall 4, arranged along the length of the vessel; upper horizontal strips 9 between the side walls 2 and the top wall 4, arranged along the width of the vessel.

The vertical strips 5 project from the side walls 1, 2 a distance L1 and have a width a1.

The maximum distance L from the list surface to the vessel walls 1, 2 is determined by the value of the accumulator cell's maximum possible specific energy (Wh / dmz) for a certain standard size thereof, the electrode width determined during the production process and the minimum thickness of the vessel that can be allowed for an accumulator cell. of a specific type in order for it to have the required strength.

The strip width a1 should be less than the distance between the projections arranged on the same wall, which makes it possible for the strips 5 to function as stiffening strips.

Hollow springs 10 are made between the strips 5 and the side walls 1, 2.

The lower horizontal strips 6 (Fig. 2) project from the bottom wall 3 a distance Lz and have a width ag.

The values of L2 and az are determined in the same way as L; and al for the lists 5.

Between the strips 6 and the lower wall 3, hollow keels -11 are made.

The radii R1, RZ of the cavities 10, 11 should not be less than the maximum distance from the surfaces of the strips 5 to the walls 1, 2 and the surfaces of the strips 6 to the wall 3, respectively, which gives a smooth transition between strips and walls which prevents the concentration of stress at the transition.

The ratio between the maximum distance from the surfaces of the strips 5, 6 to the walls and the width of the strips 5, 6 (L1 / al and Lz / az) is between 0.05 - 0.3, which makes it possible for the strips 5,6 to function as stiffening strips.

The bottom wall 3 (Fig. 2) comprises a stiffening strip 12 arranged along the width of the vessel, ie parallel to the side walls 2.

The stiffening strip 12 is made rectangular with a height hl and a width aa and arranged at the center of the wall 3, which makes it possible to achieve a uniformly distributed rigidity of the wall 3.

The height hl and the width ag have the mutual ratio hl / asg 1, which makes it possible to achieve a strip with the required rectangular section which has the highest rigidity.

Vessels of considerable length should be supplemented with a larger number of stiffening strips, uniformly distributed over the entire surface of the wall 3.

The top wall 4 of the vessel 4 (Fig. 1) comprises a stiffening strip 13 arranged along the width of the vessel, ie parallel to the side walls 2, two pole pieces 14 and a filling piece 15.

Stiffening strips 13 extend through the nozzles 14 and 15, which ensures a rigid connection between them, which in turn increases the operational reliability of the vessel.

The stiffening strip 13 is made rectangular with chamfers 16 between the stubs 14 and the top wall 4, which provides an extra rigid connection between the stub 14 and the wall 4.

The stiffening strip 13 has a height hz and a width au with the mutual ratio hz / au; 1, which makes it possible to achieve a strip with the required rectangular shape.

In vessels with a larger number (not shown in the drawing) of pole pairs, the number of stiffening strips 13 arranged on the top wall 4 is equal to the number of pairs of pole pieces 14.

According to the present invention, the height h1 of the stiffening strip 12 (Fig. 2) on the bottom wall 3 does not exceed the maximum distance L2 of the surface of the lower horizontal strips 6 from the wall 3, which gives rigidity to the vessel as a whole.

The height hz of the stiffening strip 13 (Fig. 1) on the top wall 4 is not greater than the height of the pole pieces 14 ha, since a further increase of the stiffening strip height will not improve the rigidity of the connection between the poles, but only complicates the accumulation of the battery cells.

The side walls 2 can be supplemented with (not shown in the drawing) extra rectangular stiffening strips both with and without perforations between these strips and the walls' surfaces, which increases the stiffness of the walls which take up the stress from the electrode assembly, which stress increases during cell use with electrode - the thickness increases.

The strength of one-piece plastic vessels for electrochemical chemistry was tested experimentally by introducing air into the vessels at a pressure of up to 1 atm.

Comparative testing of known analogue vessels and the proposed vessel has given the following results: - the vessels without protruding strips broke along the vertical and lower horizontal strips; the vessels with protruding strips made without hollow wedges between the strips and the walls from which they protrude broke at the transitions between the strips and the walls; and - the vessels of the proposed construction showed no cracks at this pressure.

However, when the ratio of the maximum distance of the strip surface from the vessel wall to the strip width (L1 / a1 and Lz / az) was equal to 0.05, deformation (buckling) of the vessel walls occurred as a result of insufficient rigidity. During operation, such a deformation of the vessel can cause its rupture.

A minimal deformation of the walls was observed on vessels with the ratios L1 / al and Lz / az equal to 0.3.

The strength of the vessel for impact stresses was tested by vibration testing of the functioning accumulator cells at an angle of 100 to the vertical with an acceleration of 9.8 m / sz (1 g) and a frequency up to 60 Hz for 5 hours.

Comparative testing of known analogue vessels and of the proposed vessel gave the following results: - the analogue vessels broke where three walls, ie two side walls and the bottom wall, meet; the vessels according to the proposed construction did not break at the meeting point of the three walls in case the lower horizontal strips protrude from the wall.

The rigidity of the top and bottom wall was tested using plates of the same material and with the same thickness and other dimensions as for the top and bottom wall of the vessel, the plates being arranged along the sides corresponding to the length of the vessel. The plates were subjected to loads corresponding to the weight of the electrode assembly (for the top wall) or the total weight of the electrode assembly, the vessel and the electrolyte (for the bottom wall), and the deformation (deflection) of the plates was measured.

Comparative testing has shown that the plates with stiffening strips showed less deflection than those without stiffening strips.

Claims (3)

9 447 180 Consequently, the strength of the top and bottom walls of the vessel supplemented with stiffening strips is much higher, which corresponds to the requirements imposed on the strength of these walls. The strength tests of the proposed vessel for an electrochemical cell thus confirm that this vessel has a robust construction. The proposed construction of the vessel for an electrochemical cell exhibits high strength and consequently high operational reliability. P a t e n t k r a v Vessel for an electrochemical cell made of one-piece plastic material with walls of uniform thickness and shaped like a rectangular parallelepiped-round rounded strips (5, 6, 7, 8, 9), complete with pole pieces (14) and a filling spout (15 ) which are arranged on the top wall (4) of the vessel, characterized in that the vertical strips (5) project from the side walls (1, 2) of the vessel, that the horizontal horizontal strips (6) arranged along the length of the vessel project from the bottom wall of the vessel. (3), all the strips (5, 6) being made with perforations (10, 11) to the walls (1, 2, 3) from which they project, which perforations (10, 11) are made with radii (R1). , 2) at least equal to the maximum distance (Llaz) from the surface of the strip (5, 6) to the wall of the vessel (1, 2, 3) and with a ratio between the maximum distance (L1,2) from the surface of the strip (5, 6) to the wall of the vessel (1, 2, 3) and the width of the strips (5, 6) (a1, ¿) ranging from 0.05 to 0.3, and that the vessel is further provided with at least two stiffeners strips (12, 13) arranged along the width of the vessel and with a ratio between the height (h1,2) of the stiffening strip (12, 13) and the width (a3, u) of at least 1, one stiffening strip (12) being made on the bottom wall ( 3), while the second stiffening strip (13) is made on the top wall (4) and extends through the pole pieces (14). Vessel according to claim 1, characterized in that the height (hl) of the stiffening strip (12) on the bottom wall (3) of the vessel is at most equal to the maximum distance (Lz) from the surface of the horizontal strips (6) to the bottom wall (3) of the vessel. ). 447 180 10 Vessel according to claim 1, characterized in that the height (hz) of the stiffening strip (13) on the top wall (4) of the vessel is at most equal to the height (hg) of the pole pieces (14).