BG66668B1 - Method and device for increasing the energy efficiency in the production and exploitation of lead cells and batteries - Google Patents

Abstract

The invention relates to a method and a device for increasing of the electrical and operational parameters of the lead cells and batteries and it can be applied in the industry. The method for increasing the energy efficiency in the production and exploitation of lead acid cells and batteries, wherein the lead acid cells and batteries with unformed plates are poured with an electrolyte and are subjected to formation and charging, characterized by the fact that in a part of the time of the process of formation of the positive and negative plates and/or by charging the cells and the batteries they are subject to influence by modulating low energy magnetic field in the frequency range of 1-10 Hz to 120 Hz.

Description

Field of technology

The invention relates to a method and a device for increasing the electrical and operational parameters of lead cells and batteries and will find application in industry.

BACKGROUND OF THE INVENTION

Lead-acid batteries are one of the first secondary sources of electricity. According to the design, generally lead-acid batteries are starter, traction and stationary. The service life of different types of lead batteries depending on their modification and application varies from 500 to 1800 cycles.

The total reactions that take place during charge and discharge in the battery are reversible and are represented by the general equation:

PbO2 + Pb + 2H2SO4 = 2PbSO4 + 2H2O

The main advantages of modern lead-acid batteries, which make them widely used in various fields of modern industry and people's lives are the following:

- relatively low production price;

- reliable service and production technology;

- low self-discharge;

- permissible high discharge currents;

- implemented in mass industrial production for decades;

- fully recyclable, etc.

In addition to these advantages, lead batteries have some disadvantages that to some extent limit their use, such as:

- inability to store for a long time in a diluted state due to a sharp decrease in their electrical characteristics and the likelihood of reaching complete unusability;

- low specific energy;

- limited number of cycles to full discharge;

- increasing the charging time after cycling with stronger currents, etc.

Due to these reasons, as well as due to the large-scale development of energy, transport, communication and information technologies, lead batteries are subject to high operational requirements, ie. the demand for lead-acid batteries with improved operating parameters significantly increases. This, in turn, requires the production and operation of this type of secondary sources of electricity to be placed at a new technological level.

One of the ways to increase the electrical parameters and increase the efficiency in the operation of these batteries is the application of external physical influence on the processes that take place during charging and discharging of lead batteries. Basically, patents and publications that relate to the application of physical effects such as various sound, electromagnetic and mechanical effects are for the qualification of finished lead batteries and lead cells after their production. Such is patent US 6,520,018, according to which ultrasonic waves are used to qualify the overall assembly of the battery immediately after its manufacture. There are also patents, such as U.S. Pat. No. 7,592,094, which relates to the application of ultrasonic waves, but during the operation of lead-acid batteries, in order to eliminate the degradation of the active masses in the plates of lead-acid batteries in order to increase the efficiency of charge and discharge during their cycling. In another patent JP 11 312533, ultrasonic waves are applied during the process of forming lead plate plates for a period of about 5 minutes, over a period of time, in order to remove the absorbed gases on the surfaces of the positive and negative plates in lead batteries. There is also a Bulgarian patent № 66146, according to which ultrasonic waves are applied during the formation and charging of lead batteries and cells, which shortens the formation time and produces structures of the active mass, which ensure longer battery life.

Descriptions of issued patents for inventions № 06.1 / 15.06.2018

Technical essence of the invention

The object of the invention is to provide a method as well as a device for influencing the electrochemical processes that take place during the production and operation of lead-acid batteries and cells, whereby a qualitatively new product with increased electrical and operational parameters is obtained.

The problem is solved by the proposed method, as well as a device for carrying out the method, objects of the present invention.

According to the proposed method for increasing energy efficiency in the production and operation of lead-acid cells and batteries, during part of the process of formation and / or charging of cells and batteries, they are exposed to a modulated low-energy magnetic field in the frequency range. from I ¹⁰ Hz to I ²⁰ Hz.

According to one variant of the method, the cells and batteries are exposed to a modulated low-energy magnetic field during the last 2 to 4 hours of the formation and / or charging process.

According to another variant of the method, the cells and batteries are exposed to a modulated low-energy magnetic field during the first 1/2 part or 1/3 part of the time required for formation and / or charging.

The device for carrying out the method object of the present invention includes a software-controlled control module consisting of an interconnected modulating device, a modulated magnetic field source, a modulating sinusoidal signal generator or synthesizer, a digital analog converter (DAC) and an amplifier, wherein of a modulated magnetic field includes at least one solenoid with or without a magnetic core.

The proposed method and device according to the present invention create conditions for accelerated and efficient flow of electrochemical and crystallization processes in the formation, charge and discharge of lead batteries and cells, thereby increasing their electrical and operational parameters.

The advantages of the method and the device are the following:

• increase the capacity of lead batteries or cells by more than 20%;

• shortening the charging time and reducing the energy required to charge lead batteries or cells by more than 60%;

• change of the morphology of the lead and lead dioxide materials, forming respectively the negative and positive plates in the lead batteries and cells;

• creating conditions for a more complete and efficient course of charge and discharge reactions of lead batteries and cells at low temperatures.

Explanation of the attached figures

The method and device for increasing the energy efficiency in the production and operation of lead-acid cells and batteries is illustrated by the attached figures, which only explain them, but do not limit them, whereby:

Figure 1 shows an exemplary embodiment of the device performing the method of impact by applying a low-energy modulated magnetic field during a given stage of production or when charging and discharging lead cells and batteries;

Figure 2 is a diagram showing life cycle data from cycling of two experimental 2V / 4.5Ah lead-acid cells with and without low-energy modulated magnetic field (MMP) exposure once during the initial recharging after the formation of these experimental lead -acid cells.

An exemplary embodiment of the invention

According to the attached fig. 1, the device for creating a low-energy modulated magnetic field for influencing the electrochemical and crystallization processes occurring during the production and operation of lead-acid cells and batteries includes a software-controlled control module 1 consisting of an interconnected modulating device 2, a source of modulated

Descriptions of issued patents for inventions № 06.1 / 15.06.2018 magnetic field 3, modulating sinusoidal signal generator or synthesizer 4, digital analog converter (DAC) 5 and amplifier 6. The source of modulated magnetic field 3 may include one or more solenoids with magnetic core (s). Position 7 represents a lead-acid battery or cell.

The purpose of the control module 1 is to create a time-controlled modulating sinusoidal signal with preset depending on the type, purpose and size of the lead battery (s) or cell (s), specific parameters in the frequency range from I ¹⁰ Hz to I ²⁰ Hz. Depending on the type, size and weight of the cell (s) or battery (s) being affected, the modulating signal may be amplified by an amplifier 6.

The method for increasing the energy efficiency in the production and operation of lead-acid cells and batteries is that during part of the process of formation and / or charging of the cells and batteries, they are exposed to a modulated low-energy magnetic field generated by the described device in the frequency range from I ¹⁰ Hz to I ²⁰ Hz.

According to one variant of said method, the cells and batteries are exposed to a modulated low-energy magnetic field during the last 2 to 4 hours of the formation and / or charging process.

According to another variant of the same method, the cells and batteries are exposed to a modulated low-energy magnetic field during the first 1/2 part or 1/3 part of the time required for formation and / or charging.

The proposed method and device object of the present invention are illustrated by the following non-limiting examples.

Example 1.

12V / 2.3Ah valve regulated batteries with glass wool separators are used. Both batteries are assembled with formed positive and negative plates and are filled with electrolyte without being recharged. The two batteries are then connected to a rechargeable charger for 4 hours with a charge current of 0.23A with a charge voltage limit of 2.3V. One of the two batteries is placed in the device for generating a low-energy modulated magnetic field. The effect with a modulated magnetic field continues throughout the battery charging time of 4 hours. After completion of this procedure, the two batteries are connected to cycling modules and are subjected to cycling with a charge current of 0.23A and when the charging voltage is limited to 13.6V, the batteries are recharged with 5% more capacity than shown in the previous discharge capacity cycle. The discharge is performed in a 10-hour discharge mode with a current of 0.23 A or up to a final discharge voltage of 10.2V. In this cycling mode, for a battery that is recharged without the influence of a low-energy modulated magnetic field, a final discharge capacity of 1.48Ah is reported on the first discharge cycle. For the battery, which was applied with a low-energy modulated magnetic field, a discharge capacity of 2.2Ah was reported during the first discharge cycle. The cycling of the two batteries lasted 10 cycles in the above test mode, with the unaffected battery reaching the 2.0Ah final discharge capacity of 5 ^TIA cycles and this capacity being maintained for up to 10 ™ cycles. The battery, which has been applied with a modulated magnetic field, maintains a capacity of 2.ZA throughout the test period of 10 cycles. Furthermore, it is recognized that the duration of charging the battery, which is recharged without the application of impact was 28 h and 39 min at 5 ™ ^January cycle, to the battery, on which is applied an impact to the modulated magnetic field during the initial refueling is charges on 5 ^TIA cycle for 15 h and 37 min.

Example 2.

2V / 4.5Ah lead-acid cells were made with pre-formed two positive and three negative plates and with an AGM glass wool separator. These cells were flooded with H ₂ SO ₄ at a concentration of 1.28 g / cm ³ . The two cells were then connected to a recharging charger for 4 hours with a charge current of 0.5A and a limitation of the charging voltage to 2.55V. One of the two cells is placed in the device for generating a low-energy modulated magnetic field. The application of the impact with a low-energy modulated magnetic field was performed once after assembly

Descriptions of issued patents for inventions № 06.1 / 15.06.2018 of the cell with the pre-formed positive and negative plates, only during the first 4 hours of its recharging. Then the recharging continues under the same conditions for another 6 hours. The other, determined as a reference lead cell, which has not been subjected to a modulated magnetic field, has also been recharged with a charge current of 0.5 A and a limitation of the charging voltage to 2.5 V for a period of 10 hours. After completion of recharging, the two cells are connected to cycling modules and subjected to a cycling test with a charge current of 0.5 A and when the charging voltage is limited to 2.5V, the cells being recharged by an additional 5% more than indicated in the previous discharge cycle. capacity. The life cycle tests were performed in two stages.

The first stage includes 10 cycles in 10-hour discharge mode with a current of 0.5 A until a final discharge voltage of 1.7V and subsequent charging with a charge current of 0.5A and when limiting the charging voltage to 2.5V, the cells are recharged with an additional 5 % more than the read capacity of the previous cycle.

The second stage of the test was carried out at 20-hour discharge mode with a current of 0.25A until the final discharge voltage of 1.7V and subsequent charging with a charge current of 0.5A and limiting the charging voltage to 2.5V, the cells were also recharged with an additional 5% more than the discharge capacity readings of the previous cycle.

In this test (Fig. 2), a cell that has not been exposed to a low-energy modulated magnetic field reaches 70% of its capacity at about an 80 (cycle, which is a capacity value of 3.08Ah considered the end of cell life. At the same time, the cell to which an external action was applied with a low-energy modulated magnetic field up to 120 ™ cycle has not yet reached a capacity reduction of up to 70%, and the 120 ™ cycle has a discharge capacity of 4.14Ah, which is 92 % of the nominal capacity of the experimental lead-acid cell.

Claims (4)

Patent claims A method for increasing energy efficiency in the production and operation of lead-acid cells and batteries, in which lead-acid cells and batteries with unformed plates are filled with electrolyte and subjected to formation and charging, characterized in that during part of the time of the process of formation of the positive and negative plates and / or when charging the cells and batteries, they are exposed to a modulated low-energy magnetic field in the frequency range from I ¹⁰ Hz to I ²⁰ Hz. Method according to Claim 1, characterized in that the cells and batteries are exposed to a modulated low-energy magnetic field during the last 2 to 4 hours of the forming and / or charging process. Method according to claim 1, characterized in that the cells and batteries are exposed to a modulated low-energy magnetic field during the first 1/2 part or 1/3 part of the time required for formation and / or charging. Device for generating a low-energy modulated magnetic field, characterized in that it comprises a software-controlled control module (1) consisting of an interconnected modulating device (2), a modulated magnetic field source (3), a modulating generator or a synthesizer a sinusoidal signal (4), a digital-to-analog converter (DAC) (5) and an amplifier (6), wherein the modulated magnetic field source (3) includes at least one solenoid with or without a magnetic core.