RU2408113C1 - Thermal chemical current source - Google Patents

Abstract

FIELD: electricity. ^ SUBSTANCE: thermal source of current comprises block of electrochemical elements (ECE) in casing with thermal insulation, every of which comprises serially alternating solid layers of anode, cathode, electrolyte, heating elements in rated amount, equipped with heat insulation. Block of electrochemical elements is rigidly fixed on cover of cylindrical casing along its vertical axis, the main heating elements between layers of electrochemical elements are pyroheaters, which are made of material based on mixture of finely dispersed titanium and aluminium powders and/or their salt, which are connected to system of activation of electric igniters for initiation of ECE. Additionally along outer circuit of block of electrochemical elements there is a pyroheating element in the form of bush of material of the main heating elements, heat insulation of block of electrochemical elements is arranged as composite of layers of fine-grained quartz fibre and non-woven fibrous press-material, pyrotechnical bush inside and outside is equipped with specified layers of heat insulation, and on common base, rigidly fixed on casing cover, there are electric igniters mounted for activation and indicator of working condition, at each end of ECE block there is one passive ECE, which is not connected electrically to other ECE. ^ EFFECT: provides for requirements to weight and dimension limitations, increased resource of operation due to stabilisation of thermal mode, energy intensity, with simultaneous preservation of electrochemical characteristics. ^ 1 dwg, 2 ex, 1 tbl

Description

The present invention relates to electrical engineering, to the field of backup chemical current sources on a solid, and can be used to produce a thermal current source with ionic conductivity.

A device is known for a thermal current source containing a block of electrochemical cells, each of which is equipped with solid layers of anode, cathode, electrolyte, with heat-heating elements between them, bounded on the outside by a common casing (RF patent No. 1833080, IPC H01M 6/20, publ. 05.10 .1995, BI 28/95).

The disadvantages of this device are not high enough energy consumption and short periods of operation and warranty period of storage.

It is known as the closest in technical essence to the claimed device thermal current source (TCIT) (RF patent No. 2091918, IPC H01M 6/36, publ. 09/27/1997, BI No. 27/97), containing a block of electrochemical elements, each of which is equipped with solid layers of the anode, cathode, electrolyte, heating elements, limited from the outside by a common housing with thermal insulation.

The disadvantages of the prototype include low energy intensity, low resource and level of electrochemical characteristics of a thermal chemical current source (TCIT).

The task of the authors of the invention is to develop a TCIT providing requirements for mass-dimensional restrictions with an increased service life, increased energy consumption while maintaining electrochemical characteristics.

A new technical result obtained by using the present invention is to provide requirements for mass-dimensional restrictions, increase the service life by stabilizing the thermal regime and energy consumption while maintaining electrochemical characteristics.

These tasks and a new technical result are achieved by the fact that, in contrast

from a known design of a thermal current source containing a block of electrochemical elements in a housing with thermal insulation, each of which is equipped with solid layers of anode, cathode, electrolyte, heating elements, limited from the outside by a common housing with a cover, in the proposed design, the block of electrochemical elements is rigidly fixed on the housing cover along its vertical axis, pyrone heaters are installed as the main heating elements between the layers of electrochemical elements, which are made s is made of a material based on a mixture of finely dispersed titanium and aluminum powders, in addition to the outer contour of the block of electrochemical elements, a pyroheating element is made in the form of a sleeve made of the material of the main heating elements, the thermal current source is insulated from layers of fine-grained quartz fiber and a non-woven heat-resistant fibrous press material, the pyrotechnic sleeve is located between the specified layers of thermal insulation, and on a common base, rigidly fixed to the roof ke housing, to activate the electric igniter are mounted Thich operating status indicator at the ends EHE unit installed on one passive EHE not electrically connected to other EHE.

The proposed design TCIT is explained as follows.

The drawing shows a view of the proposed thermal chemical current source, where 1 is a cylindrical body, made mainly of steel, on which is rigidly fixed, for example by welding, cover 2, which limits the tight space of the TCIT. A block of electrochemical elements (ECE) 3 is installed and rigidly fixed along the vertical axis of the cylindrical body in the sealed space of the source. 3. The block of electrochemical elements consists of the calculated number of alternating electrochemical elements proper and heating elements. Each ECE is a press bag of solid layers of the anode, electrolyte and cathode. To heat the ECE unit to operating temperature and ensure electrical connection between them, pyroheaters are installed, which are made of a material based on a mixture of finely divided titanium and aluminum powders. Each layer of the pyrotechnic element is a heat-generating pyrotechnic composition pressed into a metal shell. The pyro-heating elements system is activated when electric igniters (EV) 4 and pyrotechnic connecting elements 6 are triggered. In order to maintain the required operating temperature in the ECE unit during the TCIT operation, heat-insulating elements 8, 9, 10 are installed as integral thermal insulation on the inner surfaces of the cylindrical body 1 and cover 2 while the cover 2 is electrically and thermally insulated with heat-insulating material 11, 12.

The housing 1 and the cover 2 are made of steel with a wall thickness of 0.5 mm to 1 mm, which, as confirmed experimentally, is optimal to ensure sufficient mechanical strength of TCIT and to comply with the specified weight restrictions.

The ECE block is insulated on all sides by a heat-insulating material consisting of layers of fine-grained quartz fiber having a low coefficient of thermal conductivity.

In a heat source on a common basis 5, elements of an activation system with electric igniters (EV) 4 and an indicator of control 7 of the operating state of TCIT are installed. To ensure the required operating time of the TIT at the ends of the ECE block, one passive ECE (not electrically connected to other ECEs) is installed, which helps to stabilize the thermal regime along the axis of the ECE block.

The proposed device operates as follows. When a current pulse is applied to the electric bridge of the EV from an extraneous current source, the EV is triggered and gives a force of flame to the system of pyrotechnic connecting elements 6, made in the form of a pyrotechnic tape, during the combustion of which pyrotechnic elements installed between the ECE layers are ignited. When the operating temperature is reached, the electrolyte becomes ion-conducting, and a potential difference arises on the ECE, after which it increases to the required value, the TCIT is ready for operation.

The high temperatures of ionic melts, the use of energy-intensive electrochemical pairs (LiB-NiCl ₂ ), as has been experimentally shown, provides high specific indicators in the proposed thermal chemical current source - operating voltages (2.1-2.6 V per cell) and significant discharge current density (up to 0.5 A / cm ² in pulsed mode), which significantly exceeds the performance of the prototype.

Thus, when using the proposed thermal current source, the requirements for mass-dimensional restrictions are provided, increasing the service life and energy consumption by stabilizing the thermal regime while maintaining the electrochemical characteristics.

The possibility of industrial implementation of the proposed thermal chemical current source is confirmed by the following examples.

Example 1. In laboratory conditions, the proposed TCIT was implemented as a prototype of a thermal chemical current source. It is installed along the vertical axis in a cylindrical housing 1 (see drawing), connected by hermetic argon-arc welding with a cover 2 of 11 ECE units as a part of an ECE-3 unit. Housing 1 and cover 2 are made of stainless steel 12X18H10T GOST 5632-72 , wall thickness 0.7 mm. The ECE unit is mounted on the lid using 3 M4-7H screws. The necessary operating voltage of a thermal current source (TIT) is provided by serial connection (set in a "pole") of the entire ECE package. In the TCIT, one passive ECE is installed at the ends of the ECE block. To heat the ECE to the operating temperature and ensure electrical connection between the ECE, pyrotechnic compositions pressed into the metal shell are installed.

To maintain the required temperature in the ECE unit 3 and to limit the temperature of the housing 1, heat insulators 8, 9, 10 made of TZMK-20 TU 1-596-290-89 are installed on its inner surfaces, while the cover 2 is additionally thermally and electrically insulated with heat-insulating layers materials 11, 12 (“Cardboard-N” 4682601.013-89 TU, mica SSP GOST 13750-88).

Example 2. To increase the resource of working hours of TCIT as a prototype, the proposed device according to the conditions of example 1 is implemented, in which an additional pyroheating element is installed in the form of a sleeve 13 located between two layers of thermal insulation (internal from Cardboard-N) on the side surface of the ECE unit and external - from the material TZMK-20). The pyrotechnic sleeve serves as a heat accumulator, which allows to extend the interval for maintaining the operating temperature in the ECE unit.

The measurement results are summarized in table 1.

As the examples and data in Table 1 showed, the use of the proposed TCIT allowed to meet the requirements for mass-dimensional restrictions, increase the service life and energy consumption by stabilizing the thermal regime while maintaining the electrochemical characteristics.

Table 1 Implementation examples The name of indicators Unit. The value of the proposed TCIT The value of the TCIT prototype Expiration date THIT Note one 2 3 four 5 6 7 TCIT prototype Characteristics: Insufficiently high indicators of energy intensity, operating time, mass, reliability Current BUT Up to 3.5 A Voltage AT 21.0-30.0 V Capacity A * s 277.0 17 years Specific energy W * h / kg 6.1 Working hours from 106.0 Dimensions mm ⌀47.5 * 70.2 Weight g 310.0 Proposed TCIT Characteristics: Improvement in characteristics: operating time, removable capacity, specific energy, mass, reliability, thermal stabilization Current BUT Up to 3.5 A Voltage AT 21.0-30.0 V Capacity A * s 579.0 Specific energy W * h / kg 17.5 17 years Working hours from 199.0 Dimensions mm ⌀47.5 * 70.2 Weight g 230,0

Claims (1)

A thermal chemical current source containing a block of electrochemical elements (ECE) in a case with thermal insulation, each of which contains successively alternating solid layers of the anode, cathode, electrolyte, heating elements in an estimated amount provided with thermal insulation, characterized in that the block of electrochemical elements is rigidly fixed on lid of the cylindrical body along its vertical axis, pyroheaters are installed as the main heating elements between the layers of electrochemical elements which are made of a material based on a mixture of finely dispersed titanium and aluminum powders and / or their salts, which are connected to an activation system of electric igniters to initiate ECE, in addition to the outer contour of the block of electrochemical elements, a pyro-heating element is made in the form of a sleeve made of the material of the main heating elements, thermal insulation the block of electrochemical elements is made composite of layers of fine-grained quartz fiber and non-woven fibrous press material, pyrotechnics The electrical sleeve inside and outside is provided with the indicated layers of thermal insulation, and on a common base rigidly fixed to the housing cover, electric igniters for activation and an operating status indicator are mounted, one passive ECE is installed at the ends of the ECE unit, which is not electrically connected to other ECEs.