CN209150256U - A high-power anisotropic current battery - Google Patents

Abstract

The utility model relates to a high-power anisotropic current storage battery, which belongs to the field of storage batteries. Aiming at the problem that the current distribution consistency of the existing storage battery is poor and leads to a short service life of the storage battery, the technical solution is as follows: a high-power anisotropic current current storage battery, comprising: A battery slot for accommodating functions, a battery cover covering both ends of the battery slot, and a plurality of positive plates, separators and negative plates accommodated in the battery slot, the separators are placed between the positive plates and the negative plates, and the positive plates are Separated from the negative plate, the battery tank is provided with electrolyte, the tab of the positive plate is connected to the positive pole, the tab of the negative plate is connected to the negative pole, the positive pole and the negative pole are respectively placed on two battery covers, arranged oppositely . The positive column and the negative column are on two different surfaces. During charging and discharging, the electrolyte can participate in the reaction, the current distribution is consistent, and the current flows in the opposite direction during charging and discharging. service life is extended.

Description

A high-power anisotropic current battery

technical field

The utility model belongs to the field of accumulators, in particular to a high-power anisotropic current accumulator.

Background technique

The lead-acid battery reacts with the lead paste on the plate body through the electrolyte to achieve the purpose of charging and discharging, while the positive and negative poles of the existing lead-acid battery are on the same plane, which is usually the upper surface of the lead-acid battery. When discharging, the confluence flows in the same direction, and the upper part of the battery reacts first, and the bottom of the battery reacts insufficiently at the end of the charging and discharging process, which leads to uneven current distribution, that is, the consistency of current distribution is poor, and with the increase of use time , there will be active material sulfation, which is an irreversible reaction, which will lead to battery capacity attenuation and shortened service life.

Utility model content

Aiming at the problem of short battery life due to poor current distribution consistency of the existing battery, the utility model provides a high-power anisotropic current battery, the positive and negative poles of which are located on two opposite surfaces, so that the current distribution is uniform and the battery life is prolonged. battery life.

The technical scheme adopted by the utility model is as follows: a high-power anisotropic current-conducting storage battery, comprising a battery slot with accommodating function, a battery cover covering both ends of the battery slot, and a plurality of positive plates, separators and negative electrodes accommodated in the battery slot Plate, the separator is placed between the positive plate and the negative plate to separate the positive plate and the negative plate, the battery tank is provided with electrolyte, the tab of the positive plate is connected to the positive column, the tab of the negative plate is connected to the negative electrode The columns are connected, and the positive column and the negative column are respectively placed on the two battery covers and arranged oppositely.

The positive column and the negative column are on two different surfaces. During charging and discharging, the electrolyte can participate in the reaction, the current distribution is consistent, and the current flows in the opposite direction during charging and discharging. service life is extended.

Further, the positive pole and the negative pole are respectively arranged on the two battery covers along the diagonal direction of the battery tank. In this setting, the electrolyte is fully reacted during charging and discharging, which can achieve full diversion, effectively reduce the sulfation of active substances, and achieve the purpose of prolonging the service life.

Further, the high-power countercurrent flow battery further includes an integral valve, and the integral valve is located on the battery cover where the positive pole is located. Add acid and glue to the battery tank through the integral valve. There are bonnets and filter plates inside the integral valve. If water vapor or gas is generated inside the battery, the bonnet is lifted up, and the water vapor or gas is discharged through the bonnet and filtered. The plate isolates the electrolyte in the battery tank to prevent the electrolyte from overflowing.

Further, the tabs of the positive electrode plate and the positive poles and between the tabs of the negative poles and the negative poles are connected by a bending connecting piece, and the connecting piece is a casting and welding piece. Castings have fewer defects and are not easily corroded by electrolytes.

The use method of the above-mentioned high-power anisotropic current storage battery includes the following steps:

Step 1, the tabs of the positive plate and the tabs of the negative plate are reversely arranged in the battery tank, and a separator is arranged between the positive plate and the negative plate;

Step 2, the tabs of all positive plates are connected to the positive column by casting welding, and the tabs of all negative plates are connected to the negative column by casting welding;

Step 3: After the battery cover is covered, the electrolyte is poured into the battery tank from the integral valve to complete the assembly of the high-power anisotropic current battery;

Step 4, arranging the assembled multiple high-power anisotropic current batteries on the battery rack horizontally, and making the positive poles and negative poles of adjacent high-power anisotropic current batteries alternately arranged;

Step 5: Connect the positive pole and the negative pole of the adjacent high-power anisotropically-conducting batteries with copper bars or copper connecting bars to form a high-power anisotropically-conducting battery pack.

This arrangement enables the current generated during the charging and discharging process to run through each high-power anisotropic current battery, so that the active material sulfation is not easy to occur, and the service life of the battery is prolonged.

Further, in step 4, the horizontal arrangement of the plurality of high-power anisotropic current batteries is such that the positive pole and the negative pole face the front or rear of the battery rack.

Further, in step 5, the copper bars or copper connection bars on the rear side of the battery rack are arranged horizontally, and the copper bars or copper connection bars on the front side of the battery rack are arranged horizontally or vertically.

Further, in step 5, the positive pole of the high-power anisotropic current-conducting battery located at the upper left of the battery rack faces forward, and after it is connected with the copper bar or the copper connecting bar, it extends outward to form the positive output terminal of the current-conducting battery pack; The negative pole of the high-power anisotropic current-conducting battery located at the lower left of the battery frame faces forward, and is connected to the copper bar or copper connecting bar and then protrudes outward to form the negative output terminal of the current-conducting battery pack.

The utility model has the beneficial effects: the positive pole and the negative pole are located on two different surfaces, the current distribution consistency during charging and discharging is good, and the current flow direction is opposite during charging and discharging, the active material sulfation is not easy to occur, and the storage battery is not easy to occur. The service life of the battery is prolonged; when in use, the positive and negative columns of adjacent high-power anisotropic current batteries are alternately arranged, and the current generated during the charging and discharging process can run through each high-power anisotropic current battery, and it is not easy to appear active. The material is sulfated, and the service life of the battery is prolonged.

Description of drawings

Fig. 1 is the main sectional view of the high-power anisotropic current-conducting battery;

Fig. 2 is a sectional view of a high-power anisotropic current-conducting battery;

FIG. 3 is a schematic diagram of the front side of the battery holder;

FIG. 4 is a schematic diagram of the rear side of the battery holder;

In the figure: 1-battery tank; 2-battery cover; 3-positive plate; 4-separator; 5-negative plate; 6-positive column; 7-negative column; 8-integral valve; 9-connector; 10- Battery holder; 101-copper connection bar; 102-positive output terminal; 103-negative output terminal.

Detailed ways

The technical solutions of the embodiments of the present invention will be explained and described below with reference to the accompanying drawings of the present invention, but the following embodiments are only preferred embodiments of the present invention, not all. Based on the examples in the implementation manner, other examples obtained by those skilled in the art without creative work, all belong to the protection scope of the present invention.

As shown in FIG. 1 to FIG. 2 , the high-power anisotropic current storage battery of this embodiment includes a battery slot 1 with accommodating function, a battery cover 2 covering both ends of the battery slot 1 , and a plurality of battery slots accommodated in the battery slot 1 . The positive plate 3, the separator 4 and the negative plate 5, the separator 4 is placed between the positive plate 3 and the negative plate 5, the positive plate 3 and the negative plate 5 are separated, the battery tank 1 is provided with an electrolyte, the positive The tabs of the plate 3 are connected to the positive pole 6, and the poles of the negative plate 5 are connected to the negative pole 7. The positive pole 6 and the negative pole 7 are respectively placed on the two battery covers 2 and arranged opposite each other.

The positive pole 6 and the negative pole 7 are located on two different surfaces. During charging and discharging, the electrolyte can participate in the reaction, the current distribution is consistent, and the current flows in the opposite direction during charging and discharging, and it is not easy to occur active material sulfation. , the battery life is extended.

The reaction equation of discharge is: PbO ₂ +2H ₂ SO ₄ +Pb→PbSO ₄ +2H ₂ O + PbSO ₄ ;

The reaction equation for charging is: PbSO ₄ +2H ₂ O + PbSO ₄ →PbO ₂ +2H ₂ SO ₄ +Pb.

As shown in Figure 1, the tabs of the positive and negative plates are in different directions, and points A and B are taken arbitrarily on the positive plate, and points a and b are taken on the negative plate, and point A is away from the edge where the tabs of the positive plate are located. The vertical distance is L1, the vertical distance between point B and the edge where the tab of the positive plate is located is L3, the vertical distance between point a and the edge where the tab of the positive plate is located is L2, and the point b is from the edge where the tab of the positive plate is located. The vertical distance of the edge is L4, which satisfies L1+L2=L3+L4=plate height. In the electrochemical reaction, the current generated at point A flows to the resistance at point a, and the current generated at point B flows to the resistance at point b, A The resistance of the point + the resistance of the point a = the resistance of the point B + the resistance of the point b, so that the power inside the whole high-power anisotropic current battery is more balanced, so as to ensure the stability of the internal structure, and it is not easy to produce active material sulfation.

The positive pole 6 and the negative pole 7 are respectively disposed on the two battery covers 2 along the diagonal direction of the battery tank 1 . In this setting, the electrolyte is fully reacted during charging and discharging, which can achieve full diversion, effectively reduce the sulfation of active substances, and achieve the purpose of prolonging the service life.

The high-power anisotropic current battery further includes an integral valve 8 , and the integral valve 8 is located on the battery cover 2 where the positive pole 6 is located. Add acid and glue to the battery tank 1 through the integral valve 8. The integral valve 8 has a bonnet and a filter plate inside. If water vapor or gas is generated inside the battery, the bonnet is lifted, and the water vapor or gas passes through the bonnet. After discharging, the filter plate isolates the electrolyte in the battery tank 1 to prevent the electrolyte from overflowing.

The tabs of the positive electrode plate 3 and the positive pole 6 and between the tabs of the negative pole 7 and the negative pole 7 are connected by a bending connecting piece 9 , and the connecting piece 9 is a casting and welding piece. . Castings have fewer defects and are not easily corroded by electrolytes.

As shown in FIG. 3 and FIG. 4 , the method for using a high-power anisotropic current-conducting battery in this embodiment includes the following steps:

Step 1, the tabs of the positive plate 3 and the tabs of the negative plate 5 are reversely arranged in the battery tank 1, and a separator 4 is arranged between the positive plate 3 and the negative plate 5;

Step 2, the tabs of all positive plates 3 are connected to the positive pole 6 by casting welding, and the tabs of all negative plates 5 are connected to the negative pole 7 by casting welding;

Step 3, after the battery cover 2 is covered, the electrolyte solution is poured into the battery tank 1 from the integral valve 8 to complete the assembly of the high-power anisotropic current battery;

Step 4, arrange the assembled multiple high-power anisotropic current batteries horizontally on the battery rack 10, and make the positive poles 6 and the negative poles 7 of the adjacent high-power anisotropic current batteries alternately arranged;

In step 5, the positive pole 6 and the negative pole 7 of the adjacent high-power opposite-conduction batteries are connected by copper connecting bars 101 to form a high-power opposite-conduction battery pack.

This arrangement enables the current generated during the charging and discharging process to run through each high-power anisotropic current battery, so that the active material sulfation is not easy to occur, and the service life of the battery is prolonged.

In step 4 , the horizontal arrangement of the plurality of high-power anisotropic current batteries is such that the positive pole 6 and the negative pole 7 face the front or rear of the battery rack 10 . The high-power anisotropic current batteries are superimposed on each other, and the space utilization rate is high.

In step 5, the copper connection bars 101 on the rear side of the battery holder 10 are arranged horizontally, and the copper connection bars 101 on the front side of the battery holder 10 are arranged horizontally or vertically. This arrangement makes the arrangement of the copper connection bars 101 more regular, neat and beautiful.

In step 5, the positive pole 6 of the high-power anisotropic current-conducting battery located at the upper left of the battery frame 10 faces forward, and is connected to the copper connecting bar 101 and protrudes outward to form the positive output terminal 102 of the current-conducting battery pack; The negative pole 7 of the high-power anisotropic current-conducting battery at the lower left of the frame 10 faces forward, and is connected to the copper connecting bar 101 and protrudes outward to form the negative output terminal 103 of the current-conducting battery pack.

The above are only specific embodiments of the present utility model, but the protection scope of the present utility model is not limited thereto. Those skilled in the art should understand that the present utility model includes but is not limited to the accompanying drawings and the above specific embodiments. content of the description. Any modifications that do not depart from the functional and structural principles of the present invention are intended to be included within the scope of the claims.

Claims (4)

1. a kind of incorgruous water conservancy diversion battery of high power covers the battery at battery case both ends including the battery case with receiving effect Lid, and the multiple positive plates, isolation board and the negative plate that are contained in battery case, the isolation board are placed in positive plate and negative plate Between, positive plate and negative plate are separated, electrolyte is equipped in battery case, which is characterized in that the tab and positive terminal of positive plate It is connected, the tab of negative plate is connected with negative terminal, and positive terminal and negative terminal are respectively placed on two battery covers, positioned opposite.

2. the incorgruous water conservancy diversion battery of high power according to claim 1, which is characterized in that the positive terminal and negative terminal edge The diagonal of battery case is separately positioned on two battery covers.

3. the incorgruous water conservancy diversion battery of high power according to claim 1, which is characterized in that it further include an integral valve, it is described Integral valve is located on the battery cover where positive terminal.

4. the incorgruous water conservancy diversion battery of high power according to claim 2 or 3, which is characterized in that the tab of the positive plate By being connect in the connector of bending between positive terminal and between the tab and negative terminal of the negative terminal, the company Fitting is cast welding part.