RU2685704C1 - Ampoule-type chemical current sources - Google Patents

Abstract

FIELD: electrical engineering.SUBSTANCE: invention relates to the field of electrical equipment, namely to the ampoule-type chemical backup current sources (ACCS) containing in the single housing with the cover the rated number of the electrolyte units and the corresponding number of the electrodes sections arranged in the electrode unit, each of which contains a zigzag-like cathode, an anode and each section is equipped with an individual bellows-type ampoule filled with thionyl chloride-based electrolyte, and means for mechanical opening of each of the ampoules simultaneously actuated from the pressure pulse source, wherein each electrode section section of electrode unit is spatially separated from each other on periphery of each housing of each section of electrodes by a layer of ceramic insulation, in the electrolyte unit in its central part there is a blocking device for prevention of unauthorized axial movement of the bellows bases of the ampoule with electrolyte when overheated. Locking device is made in the form of a bushing rigidly fixed on the stop, on the free end of which there fixed by means of laser welding are two fixed retainers in the form of semi-rings, which are inserted into the annular groove made along the external lateral surface of the lower movable base of the ampoule, with the possibility of axial movement of the opposite ampoule base in the direction to the ampoule opening element at the specified ACCS cocking moment.EFFECT: high reliability of ACCS at high ambient temperatures while maintaining level of charging characteristics is technical result of invention.1 cl, 1 dwg, 2 ex

Description

The alleged invention relates to the field of electrical engineering, to chemical backup current sources with thionyl chloride electrolyte, which are activated from a physical factor, specifically to chemical ampoule current sources (AHIT) and can be used, in particular, in products with a limited instrumental volume.

The urgency of the problem to be solved is based on the need to develop tools that eliminate the risk of unauthorized activation of AHIT occurring due to exposure to high ambient temperatures, or instruments and equipment located in close proximity to them.

The prior art AHIT (RF Patent No. 2191448, IPC Н01М 6/34, publ. 10/20/2002), in which the electrode units, ampoules filled with a non-aqueous electrolyte based on thionyl chloride, and a source of pressure pulse are provided in a single package . Ampoules are made in the form of bellows and are combined with electrode blocks into a single electrochemical cell (ECE). Electrode blocks are filled with inert gas under pressure below atmospheric. On the movable lid (lower base) of the ampoule a collapsing membrane is tightly fixed. On a fixed base of each electrode unit, made perforated, means for opening ampoules, which are simultaneously activated from the pressure pulse of the gas generator, are rigidly fixed.

Known AHIT (RF patent №02290723, IPC Н01М 6/10, publ. 12/27/2006), containing in the case with a lid, cap and a perforated partition to inject electrolyte into the electrode units, at least one vial with electrolyte based on thionyl chloride, the estimated number of electrode units with ECE sections, while the ampoules are made in the form of bellows with movable bases and elements of ampoules opening on them, which are simultaneously triggered by the pressure pulse of the gas generator.

The disadvantages of analogs include the lack of funds that provide for the elimination of the risk of unauthorized activation of AHIT that occurs when AHIT is overheated due to exposure to high ambient temperatures, or overheating of instruments and equipment located in the immediate vicinity of AHIT.

The task of the authors of the proposed AHIT is to develop a design in which means are provided to eliminate the risk of unauthorized AHIT triggering, which occurs when AHIT is overheated due to exposure to high ambient temperatures.

A new technical result achieved when using the proposed AHIT is to improve the reliability of AHIT by reducing the risk of unauthorized AHIT triggering due to high environmental temperatures while maintaining the level of discharge characteristics.

These tasks and new technical result are ensured by the fact that, in contrast to the well-known AHIT, containing in a single case with a cover the estimated number of electrolyte units and the corresponding number of electrode sections placed in the electrode unit, each of which contains a zigzag anode, placed in the gaps between the folds of its cathodes in a calculated amount, on the surface of which layers of composite separators are made, each section of electrodes is equipped with an individual ampoule of bellows type and with a corrugated side wall and movable bottom with a breakthrough membrane made in it, and upper bases filled with an electrolyte based on thionyl chloride, and means for mechanical opening of each of the ampoules, all of which are installed with the possibility of simultaneous activation of a pressure pulse from the source, each section of the electrodes of the electrode unit is spatially separated from the other along the periphery of each body of each section of electrodes with a layer of ceramic insulation in the electrolyte unit in e The central part is fitted with a locking device to prevent the overheating of unauthorized axial movement of the bellows bases of the ampoule with electrolyte, made in the form of a sleeve rigidly fixed to the stop, at the free end of which two fixed retainers in the form of semicircles embedded in an annular groove made on the outer the side surface of the lower movable base of the ampoule, with the possibility of axial movement of the opposite base of the ampoule in the direction of the element vsk digging ampoules at a given moment of cocking AHIT.

The proposed AHIT is explained as follows. FIG. 1 shows a general view of AHIT, where 1 is the electrolyte block (ampoule), 2 is the electrolyte block of the AHIT electrolyte block, 3 is a sleeve with 4 two fixings, 5 is the upper base of the ampoule, 6 is the plug of the ampoule for electrolyte pouring, 7 is the fixed base of the body electrolyte block, 8 - the lower movable base of the ampoule, 9 - annular groove for fixing clamps for fixing the sleeve, 10 - opening element of the ampoule, 11 - emphasis of the sleeve in the upper movable base of the electrolyte block AHIT.

AHIT contains in a single housing with a cover the estimated number of electrolyte blocks bounded by housing 2 and the corresponding number of rectangular sections of electrodes placed in the electrode unit, on the surface of which layers of composite separators are made (not shown). Each of the sections contains a zigzag-shaped anode with its cathodes placed in the intervals between the bends in the calculated amount. Each section of the electrodes is equipped with an individual ampoule 1 of the bellows type with a corrugated side wall filled with thionyl chloride-based electrolyte and an opening element 10 of each ampoule.

All ECE are located to save space in the form of a "snake", the links of which are composed of layers of electrodes, separators and layers of electrical insulation between them, which are stacked in a zigzag manner.

Electrode blocks AHIT collected from serially connected individual ECE, which are connected to the ampoule 1 with a non-aqueous electrolyte based on thionyl chloride. Between each ECE placed insulating strip of slyudinit.

The proposed AHIT also provides elements for opening 10 ampoules with electrolyte that are triggered simultaneously from a pressure pulse.

All elements of the opening 10 of each ampoule are installed with the possibility of their simultaneous activation from a single source of pressure impulse in the system of activating AHIT. Each section of the electrodes of the electrode unit is spatially separated from the other along the periphery of the cases of the sections of electrodes with a layer of ceramic insulation to remove heat when the AHIT is overheated. A blocking device 3 is installed in the electrolyte unit in its central part on the lower movable base to prevent axial movement of the lower base 8 of the bellows of the ampoule 1 with electrolyte when the AHIT is overheated. The locking device is a rigidly fixed to the stop in the lower base of the electrolyte unit (essentially in the lower movable base of the ampoule), a hollow sleeve 3, which circumscribes the electrolyte unit at the periphery. Along the contour of fixing the hollow bushing, two half-rings (clamps 4) fit into the cavity of the annular groove 9, made on the outer side surface of the lower movable base 8 of the ampoule. The sleeve 3 rests on the upper movable base 5 by means of the stop 11. A hole is provided to fill the electrolyte into the electrolyte unit. The hole is blocked by a stopper 6. The electrolyte unit case is bounded below by a fixed base 7, which serves to attach the electrolyte unit to the AHIT electrode unit.

Electrolyte block AHIT assembled as follows.

First, a hollow sleeve 3 is made with a through hole, the diameter of the end part of which is larger than the diameter of the main part of the sleeve, which is designed in such a way that an annular L-shaped protrusion (stop 11) is formed along the outer contour of the upper base 5 of the sleeve 3 to rest on the upper movable base 5 ampoules 1. On the opposite and movable base 8 of ampoule 1, an annular groove 9 is made in the center of its side surface. On the opposite side of the ampoule 5 fixed to the top base 5, sleeve 3 is welded with a free edge circumferentially to the side surface of the half-rings 4 after installing said half-rings (retainers) in the annular groove 9 along the periphery of the lower base 8 of the ampoule 1. The two semi-rings are the locks 4, thus fitting on the fixing contour of the hollow bushing 3, and enter the cavity of the annular groove 9, made on the outer side surface of the lower base 8 of the ampoule 1.

Two half rings 4 are welded mating areas to the hollow sleeve 3.

After installation of the hollow sleeve 3 together with the clamps 4 in the electrolyte unit assembly cover the periphery of the housing 2 electrolyte unit.

The proposed AHIT works as follows.

Initially, a pressure impulse is supplied from the source to the internal cavity of the electrolyte block, leading to the displacement of the movable bases 8 of the ampoule 1 towards the piercer 10 for opening the membranes separating the electrolyte and electrode blocks and opening electrolyte access to the electrode block. Thus, there is an authorized activation of AHIT, which is recorded by the indicator of the operating status of AHIT (not shown). In the event that such a moment does not occur, then due to the locking by the retainers 4, the axial movement of the movable bases 8 of the ampoule 1 and the hollow sleeve 3 of the AHIT is not brought to a working state.

When AHIT is stored in the event of overheating, the bottom base of the 8 ampoule may unauthorized move down to the opening elements 10 of the ampoule 1 and unauthorized operation of the source may occur. To prevent such movement, a sleeve 3 is provided, which is connected to clamps 4, when triggered, such movement will not occur due to the locking of clamps 4 in the annular groove 9. At the specified moment of AHIT operation, the upper base 5 under the influence of a pressure pulse together with a ring fixed on it two clamps 4 sleeve 3, sleeve 3, with the lower base 8 connected to this sleeve move towards the piercer 10. And thus, the proposed fixation mechanism does not prevent the activation of AHIT in the given time response and provides thereby improving the reliability and independence of emergency (when overheated) in its environment.

The presence of hard mass-dimensional restrictions for the proposed AHIT and the need to ensure a high level of discharge electrical characteristics leads to the compulsory compaction of the overall design of AHIT, and therefore, the assembly of all AHIT components is carried out on two dielectric bases.

As shown by experiments, using the proposed AHIT, a new technical result is achieved, which consists in increasing reliability during operation and storage by eliminating the possibility of unauthorized operation of the device when it overheats, while maintaining the high density of assembly of the AHIT assembly.

The possibility of industrial implementation of the proposed AHIT is confirmed by the following examples.

Example 1. In laboratory conditions, this AHIT was tested on a prototype in which a fixing device was made to stop the axial movement of the moving bases of the ampoule (Fig. 1).

The case of the electrolyte unit 2, the lower and upper movable bases 5,8 and the ampoule 1 are made of steel grade 12X18H10T. Sleeve 3 and clamps 4 are made of steel 14X17H2. The opening element of ampoule 10 is made of steel 14X17H2. As electrolyte in AHIT used liquid thionyl chloride, poured through the hole in the upper base of the electrolyte unit, blocked by a stopper 6.

Under the experimental conditions, extreme environmental conditions (250 ° C) were simulated, and it was shown that this device was not activated. The efficiency of such an assembly was tested for readiness to work at a given moment by applying an electrical impulse to the gas generator. Tripping occurred in normal mode.

Example 2. Under the conditions of this example, the assembly was tested in the absence of a blocking sleeve 3. When an overheating condition, an unauthorized AHIT triggered with a loss of its working capacity occurred.

Thus, as shown by experiments, the proposed technical result was achieved when implementing the proposed AHIT, namely, increasing the fire and explosion safety and reliability of AHIT by reducing the risk of unauthorized AHIT that occurs due to high environmental temperatures.

Claims (1)

Ampoule chemical current source (AHIT), containing in a single housing with a cover the estimated number of electrolyte units and the corresponding number of electrode sections placed in the electrode unit, each of which contains a zigzag anode, with its cathodes placed between the bends in the calculated amount, on the surface of which layers of composite separators are made, each section of electrodes is provided with an individual ampoule of bellows type with a corrugated side wall and movable upper and lower with a breakthrough membrane made in it, bases filled with thionyl chloride electrolyte, and means for mechanical opening of each of the ampoules, all of which are installed with the possibility of simultaneous activation of a pressure pulse from a single source, characterized in that each section of electrode electrodes of the electrode unit is spatially separated from another on the periphery of each body of each section of electrodes with a layer of ceramic insulation; a blocking device is installed in the electrolyte unit in its central part to prevent the overheating of unauthorized axial movement of the bellows bases of the ampoule with electrolyte, made in the form of a sleeve rigidly fixed to the stop, at the free end of which two fixed retainers in the form of semicircles embedded in an annular groove made on the outer side surface of the lower moving base were fixed by laser welding ampoules, with the possibility of axial movement of the opposite base of the ampoule in the direction of the element opening the ampoule at a given moment of cocking AHIT.

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