RU86049U1 - PORTABLE AUTONOMOUS ELECTROCHEMICAL CHARGING DEVICE - Google Patents

Abstract

1. Portable stand-alone electrochemical charger (PAEZU) based on an electrochemical battery containing at least one electrochemical cell, which contains a housing and a gas diffusion cathode, an anode with consumable anode material and an electrolyte, characterized in that as an electrochemical the element is a metal-air element containing a box-type housing, a expendable rectangular plate anode, gas diffusion air cathodes mounted in the walls of the housing, an electric litnuyu chamber disposed between the cathodes, the anodes are placed in the electrolyte chamber. ! 2. PAEZU according to claim 1, characterized in that the ratio of the width of the electrodes to their height is 1.5 ÷ 2.5, and the ratio of the distance between the cathodes inside the cell to the thickness of the anode is 3 ÷ 5. ! 3. PAEZU according to claim 1, characterized in that the housing of each element in the upper part is provided with flanges on both sides flush with the outer walls of the cells facing the neighboring battery cells, one side of each of the extreme elements faces the neighboring element, and the second the side faces toward the adjacent end wall of the battery, the housing of each element in the middle and lower parts contains protrusions located to the sides as well as the sides, and in width along the edges of the cathode flush with the outer walls of the elements, the protrusion The flanges, protrusions and walls of each element are the same and equal to half the air gap between the elements, the flanges and protrusions of adjacent elements are glued together, and at the extreme elements they are glued to the end wall of the device, the cathodes of each element are connected�

Description

The utility model relates to electrical engineering, namely to portable stand-alone chargers based on an electrochemical battery for charging batteries of mobile electronic devices (mobile phones, cameras, etc.).

Known portable charger Solidus 1, which works in the presence of direct sunlight (Andrey Krupin "Stand-alone charger for phones", published August 30, 2005, http://www.computerra.ru/gid/prodig//224633/). The disadvantage of this charger is that its use requires sunlight.

A portable electrochemical charger is known - a Nokia DC-8 pocket-sized additional power supply operating from a chemical current source — an element or a battery — placed in its housing (Phone Catalog, Nokia Company, 2008, Accessories section). The capacity of the popular manganese-zinc element allows you to carry out no more than one to two cycles of charging the battery of a mobile phone and, therefore, the Nokia DC-8 user must have a supply of elements in an amount of not less than half the intended number of days to use this device. In addition, the capacity of the cell used to charge the battery, the average discharge voltage of which is 1.2 V, is reduced due to the use of a DC voltage converter in the device, the efficiency of which drops sharply at a given low discharge voltage. Another disadvantage is the limited shelf life of the elements.

As for powering the charger from the battery, the use of the battery is even more irrational, since, firstly, this battery itself needs a charge, and secondly, the shelf life of the capacity in a charged battery is insignificant.

Of the known portable chargers, the closest in essential features and technical result achieved is a portable charger based on an electrochemical battery with a fuel cell containing a gas diffusion air cathode, an anode with a consumable material, metal borohydride in an alkaline electrolyte, adopted as a prototype ("Products", Medis Technologes Ltd, http://www.medistechnologes.com/products.asp?id=135 and http://www.medistechnologes.com/products.asp?id=136 published May 2, 2006). A fuel cell may have a large capacity. In the prototype, ampoules are used for fueling, which complicates the operation of the device. The disadvantage is that the element is designed to operate on the principle of a renewable current source with a periodic change of the fuel-alkaline mixture after its production (B.C. Bagotsky, A.M. Skundin “Chemical current sources”, M., Energoizdat, 1981, p. 344). Storage of ampoules with an alkaline electrolyte and borohydride, removal of spent fuel-alkaline mixture from the cell, and new refueling of the cell are inconvenient and dangerous operations that require increased caution, with the wide use of this charger, complicated difficult to fulfill conditions for preventing unauthorized persons from reagents and operations, and especially children. The use of alkali causes requirements for sealing the device, complicating its design. A significant drawback, limiting the widespread use of the device and causing its appreciation, is the use of platinum.

The objective of the utility model is to simplify and reduce the cost of a structure suitable for widespread use.

The specified technical result is achieved in that a portable stand-alone electrochemical charger (PAEZU) based on an electrochemical battery containing at least one electrochemical cell, each of which contains a housing and a gas diffusion cathode, an anode with a consumable anode material and an electrolyte placed therein, in this case, a metal-air element containing a box-type case, a expendable rectangular plate anode, and gas diffusion air are taken as an electrochemical cell. e cathodes mounted in the walls of the housing, an electrolyte chamber located between the cathodes, while the anodes are placed in the electrolyte chamber. The use of a metal-air element simplifies and reduces the cost of PAEZU through the use of plate anodes from available material and the exclusion of the use of platinum.

It is advisable that the ratio of the width of the electrodes to their height is 1.5 ÷ 2.5, and the ratio of the distance between the cathodes inside the cell to the thickness of the anode is 3 ÷ 5. When the ratio decreases below 1.5, the flotation of the electrolyte becomes more difficult, which reduces the discharge characteristics, and the mechanical stability of the device deteriorates, and when the ratio is exceeded more than 2.5, the dimensions of the device increase in plan. The lower limit of the ratio of the distance between the cathodes inside the cell to the thickness of the anode, equal to 3, provides the necessary amount of electrolyte to be poured into the cell. A decrease in this ratio below 3 will lead to a negative effect on the energy parameters of the difficulty in flotation of the electrolyte, as well as to the risk of a short circuit between the anode and cathode by accidental conductive inclusions in saline solution when the device is widely used. Exceeding this ratio over 5 will lead to an increase in ohmic losses in the electrolyte.

It is advisable that the case of each element in the upper part be fitted with flanges on both sides flush with the outer walls of the cells facing the sides of the neighboring battery cells, one side of each of the extreme elements faces the neighboring element, and the second side faces the adjacent end wall of the battery , the casing of each element in the middle and lower part contains protrusions located to the sides as well as the sides, and along the width along the edges of the cathode flush with the outer walls of the elements, the protrusion of the side s, protrusions and walls of each element equally and equal to half the air gap between the elements, the sides and protrusions of adjacent elements are glued together, and at the extreme elements they are glued to the end wall of the device, the cathodes of each element are connected by a bus enveloping the element, the end walls of the device have legs, the wires of the down conductors of the anodes are connected to the anodes by a one-piece connection, and on top of the device is closed by a lid. The described design of the PAEZU provides guaranteed sizes of air gaps and the integration of electrochemical elements into a battery. Permanent connections of elements in the form of adhesive joints along the sides and protrusions, as well as between the extreme elements and end walls provide mechanical strength of the device. At the same time, the glued sides perform the functions of the roofs of air cavities, protecting them from water ingress when filling the elements with electrolyte and due to weather conditions. The use of the protrusions provides the creation of the design of the air cavity, open from the sides and bottom of the device. At the same time, the air gap between the elements into which the two cathodes are facing is twice as large as the width of the gap between the extreme element and the end wall of the device into which one cathode is facing.

It is advisable that the solution of sodium chloride in water be taken as the electrolyte at a concentration of sodium chloride in the solution of 2 ÷ 15%. Said electrolyte solution is cheap and widely available. The lower limit of the salt concentration in the solution, amounting to 2%, allows the use of sea water in seas of low salinity. Lowering the limit below 2% will lead to an increase in the resistance of the electrolyte and, as a result, to a decrease in the electrical characteristics of the device. The upper limit of the concentration of salt in the solution, equal to 15%, provides high discharge characteristics, however, exceeding this limit will cause useless salt consumption.

It is advisable that side walls with slots opposite the air cavities be attached to it,

It is advisable that the side and end walls were made as a whole. The side walls connected to the device increase its strength and close the tires, and the slots in these walls opposite the air cavities provide air to the air cavities between the elements.

The combination of side and end walls in one piece allows you to create a shell of the device, simplifying its design.

The permanent connection of the wires of the down conductors to the anodes ensures the reliability of the electrical circuit and the convenience of removing the replaced anodes from the elements.

The legs on the end walls of the device provide air to the open lower edges of the inter-element air cavities.

It is advisable that the device is equipped with interchangeable anodes and a simple dosing device for pouring electrolyte into the cell, the volume of which is 0.6-0.8 of the internal volume of the cell. The presence of interchangeable anodes allows to increase the service life of the device. The lower limit of the ratio of the volume of the metering device for filling the electrolyte into the cell to the internal volume of the cell, equal to 0.6, ensures the normal operation of the device. If the ratio decreases below the lower limit, the energy parameters of the device will decrease due to electrolyte deficiency. Exceeding the upper limit of the ratio above - 0.8 makes it possible to reduce the energy parameters of the device due to the occurrence of leakage currents due to the appearance of an electrolyte bridge between the elements connected in series, because during the discharge of cells, the volume of electrolyte filled with reaction products increases.

The essence of the utility model is illustrated by drawings, which depict:

Figure 1 - Side view of the device (without side wall),

Figure 2 - Top view of the device (without side walls and cover),

Figure 3 - View of the device from below,

In Fig.4 is a perspective view of the device along arrow A in Fig.1 (without end and side walls and cover),

Figure 5 - View of the device from the end wall,

Figure 6 is a side view of the device with a side wall.

The device 1 consists of elements 2, each of which contains a body 3 of insulating material, in the guide groove 4 of the inner cavity of which 5 is placed an anode 6 of aluminum alloy. Gas diffusion cathodes are mounted in both transverse walls 7 of the housing 3 of each element 8. In each element, the cathodes are connected by a bus 9 to which a positive current collector of the element is connected. In this case, the adjacent bus elements are facing in different directions of the device. The transverse walls 7 of the housing 3 of the element 2 in the upper part contain the sides 10, and in the middle and lower parts contain the protrusions 11 and 12, the protrusion of the sides 10 and the protrusions 11 and 12 beyond the transverse walls 7 is the same. The sides and protrusions of adjacent elements are interconnected by an integral connection, for example, by gluing, forming a gap 13. between the transverse walls 7 of adjacent elements, into which two cathodes are facing, one from each element. The flanges and protrusions of the end elements are also connected by an integral connection, for example, gluing to the end walls of the device 14. Moreover, between the transverse wall of the end element containing one cathode and the end wall of the device, a gap 15 is formed twice as small as the gap 13 between adjacent elements. The gaps 13 and 15 are open on the side and bottom of the device. Along all elements on the sides of the device can be placed side walls 16 made of insulating material, attached to all elements by an integral connection, for example, gluing, covering tires 9. Side walls 16 contain slots 17 opposite the gaps between the transverse walls of adjacent elements and slots 18 opposite the gaps between transverse walls of the extreme elements and the end walls of the device. The end walls 14 of the device are equipped with legs 19, forming a gap 20 between the device and the surface 21 on which it is installed. Option: side and end walls can be combined into a single shell of the device (not shown in the drawing). The device is closed by a removable cover 22 of insulating material. The elements are connected in series, the anode collector wire at one end is connected to the anode by one-piece connection, and the other end contains a plug inserted into the mate of the cathode collector (collectors, switching elements and current outputs from the device are not shown in the drawing).

The charger is equipped with sets of interchangeable anodes and a simple electrolyte metering device.

The device works as follows: remove the cover 22, pour in (inject) an electrolyte and close the cover. When the device is operating through the lateral edges of the gaps 13 and 15, the device is ventilated with fresh air entering the cathodes and the exhaust is removed, reinforced by blowing through its lower edges of these gaps. One electrolyte charge is enough for 2-3 charges of a mobile phone. After these charges, the lid is removed, the electrolyte is drained, the internal cavities of the cell bodies are rinsed with any water, the electrolyte is again poured and the lid is closed. After 8-10 such cycles, anodes 4 are removed for their down conductors and new anodes are installed in the grooves of 4 cases 3.

The portability of the claimed utility model is characterized by its small overall dimensions: 80 × 63 × 60 mm, mass without electrolyte - 200 g, with electrolyte - 300 g.

In the utility model, there is no platinum (in many current sources with an air cathode it is used as a catalyst), this allows to reduce the cost of the device and thereby ensure its widespread use.

Claims (9)

1. Portable stand-alone electrochemical charger (PAEZU) based on an electrochemical battery containing at least one electrochemical cell, which contains a housing and a gas diffusion cathode, an anode with consumable anode material and an electrolyte, characterized in that as an electrochemical the element is a metal-air element containing a box-type housing, a expendable rectangular plate anode, gas diffusion air cathodes mounted in the walls of the housing, an electric litnuyu chamber disposed between the cathodes, the anodes are placed in the electrolyte chamber. 2. PAEZU according to claim 1, characterized in that the ratio of the width of the electrodes to their height is 1.5 ÷ 2.5, and the ratio of the distance between the cathodes inside the cell to the thickness of the anode is 3 ÷ 5. 3. PAEZU according to claim 1, characterized in that the housing of each element in the upper part is provided with flanges on both sides flush with the outer walls of the cells facing the neighboring battery cells, one side of each of the extreme elements faces the neighboring element, and the second the side faces toward the adjacent end wall of the battery, the housing of each element in the middle and lower parts contains protrusions located to the sides as well as the sides, and in width along the edges of the cathode flush with the outer walls of the elements, the protrusion the edges, protrusions and walls of each element are the same and equal to half the air gap between the elements, the edges and protrusions of adjacent elements are glued together, and at the extreme elements they are glued to the end wall of the device, the cathodes of each element are connected by a bus enveloping the element, the end walls the devices have legs, the wires of the down conductors of the anodes are connected to the anodes by a one-piece connection, and on top of the device is closed by a lid. 4. PAEZU according to claim 1, characterized in that the solution of sodium chloride in water is taken as the electrolyte at a concentration of sodium chloride in the solution of 2 ÷ 15%. 5. PAEZU according to claim 1, characterized in that the adjacent bus elements are facing in different directions of the device. 6. PAEZU according to claim 1, characterized in that it is connected to the side walls with slots opposite the air cavities. 7. PAEZU according to claim 1, characterized in that the side and end walls are made as a unit. 8. PAEZU according to claim 1, characterized in that it is equipped with interchangeable anodes. 9. PAEZU according to claim 1, characterized in that it is equipped with a simple dosing device for pouring electrolyte into the cell, the volume of which is 0.6-0.8 of the internal volume of the cell.