RU2233428C1 - Detonating device of mechanical fuse - Google Patents

Abstract

FIELD: detonating devices of an impact mechanical fuse actuated by a preset mechanical force, used in blasting operations in the oil and gas extractive industry.

SUBSTANCE: placed in succession in the device body are a striker, deformable member, primer detonator, axial duct, lead charge, block-detonator, the stepped striker is freely installed and fixed on the surface of the deformable member by a nut turned on the body and having a partition with a hole, whose diameter equals the lesser diameter of the stepped cylindrical striker. The lead charge and the block-detonator are made as a separate assembly having an aluminum cap with a weight of powder of high explosive pressed in it to a half of its height, inserted closely to the block-detonator of thermoplastic high explosive and having a shaped recess in the lower part lined with metal foil and closed with the aluminum cap. The lead charge-block-detonator assembly is fixed by a nut having a hole in its partition, whose diameter is less than the diameter of the aluminum cap closing the block-detonator.

EFFECT: enhanced reliability of device operation, reduced value of the impact minimum energy required for its operations, improved adaptability to manufacture and enhanced safety at assembly of the device.

4 cl, 1 dwg

Description

The invention relates to blasting, and more specifically to fuses that are fired from a given mechanical force. The invention can be used in the design of the detonating device of a mechanical shock fuse.

Known detonating device of a mechanical fuse (see German patent No. 1209464, CL 72 i 3/02, 1962). The device is used to initiate an explosion of ammunition charges and includes a detonator capsule detonator with an initiating explosive (BB) located in a metal case, a transfer charge (usually from a low-density blasting explosive) and a checker-detonator (a checker from a high-density blasting explosive capable of reliably initiate detonation of ammunition charges). The detonating device is triggered when a detonator capsule is pricked with a stinger of a striker with a certain force. From the detonator capsule, the explosion propagates into the transfer charge and further into the detonator block.

The disadvantage of the detonating device of this design is the increased danger during production operations, due to the fact that the detonator capsule containing the initiating explosive has an extremely high sensitivity to various kinds of external influences (shock, vibration, fire beam, etc.).

Of the known detonating devices of a mechanical fuse, the closest (in technical essence) to the claimed technical solution is the detonating device described in the patent of the Russian Federation No. 2083948, IPC 6 F 42 C 19/10, (figure 1), bull. No. 19, 1997

This detonating device of a mechanical fuse is used to initiate an explosive chain of cumulative perforators, lowered into oil and gas wells on tubing (tubing), and contains a housing with a detonator capsule in it, which is a blast of a blasting explosive pressed into the upper hole case, transfer charge and detonator saber. An axial channel is made in the housing between the transfer charge and the detonator capsule, a cylindrical firing pin is located above the detonator capsule, a deformable element (made of an inert material of aluminum foil) is installed between the detonator caps and the firing pin. In this case, the fastening of the striker in the hole of the housing is carried out using glue.

A disadvantage of the known design of the detonating device of a mechanical fuse is that the device has low reliability at a set (regulated) value of the minimum mechanical impact energy required to detonate the detonator capsule. This is due to the fact that the fastening of the striker in the hole of the housing is carried out using glue. Fixing is carried out by applying a thin layer of glue manually on the side surfaces of the striker and the hole, installing the striker in the housing hole until the surfaces of the striker and the deformable element are made of an inert material located above the explosive block of the detonator capsule, and the adhesive is polymerized. In this case, the flow of glue to the deformable element and the detonator capsule is not excluded, which leads to an increase in the bonding area and, as a result, to an increase in the shear strength of the adhesive joint. A similar method of fastening the striker in the opening of the housing determines the instability of the shear strength, which can exceed the normalized minimum value of the mechanical shear force of the striker in the hole, and therefore leads to an increase in the impact energy required to detonate the detonator capsule.

When working in well conditions, due to the increased adhesive strength of the striker and the body, the impact of the shock pulse is not enough to start the process of exciting the explosive transformation of the detonator capsule, which leads to failure - failure of the detonation device at the set minimum value of the energy of the shock pulse. The minimum value of the impact energy given by the design of the trigger mechanism of the explosive (initiating) head is a constant value for this type of head.

Another disadvantage of the known design of the detonating device of a mechanical fuse is the low density of the transfer charge (not more than 1.33 g / cm ³ ), consisting of a powdered blasting explosive - HMX. Given the actual operating conditions of the device in the well (mechanical shocks, vibration, etc.), the possibility of compaction of the transfer charge and the appearance of an air gap between the axial channel and the surface of the transfer charge cannot be ruled out. This leads to a slowdown in the increase in pressure during the combustion of the transfer charge and the transition of this combustion to stable detonation. With a further increase in pressure, its value may exceed the shear force of the adhesive joint of the cap-detonator cap-body system, as a result of which the explosive burns out, the gas jet is expelled and the checker-receiver of the first perforator module is destroyed without detonation. In addition, a plane shock wave with a normalized air gap between the device’s detonator-checker and the receiver-checker of the first punch module with the above disadvantages is characterized by instability of parameters, which can lead to interruption of detonation in this area.

The objective of the present invention is to increase the reliability of operation of the detonating device at a set value of the minimum impact energy, reducing the minimum value of the impact energy required to use the device by using a cylindrical step striker without the use of glue, which will expand the range of use of the device and use it in various types of explosive heads, increasing the reliability of detonation transmission through the normalized air gap to the explosive chain checker receiver the first module of the perforator by using a detonator block with a cumulative recess lined with metal foil, as well as improving manufacturability and safety during assembly of the device by using a transfer charge and a detonator block in the form of a finished assembly fixed by a nut.

To achieve this goal, a design of a detonating device of a mechanical fuse based on a blasting explosive is proposed, consisting of a cylindrical hammer located in the housing sequentially on the same axis installed in the housing opening, a deformable element, a detonator capsule, which is a pressed checker from a blasting explosive, an axial channel of small diameter, not containing explosives, transfer charge and detonator drafts made of blasting explosives. The cylindrical firing pin, in contrast to the known design, is made stepwise and mounted on a detonator capsule with a large diameter through a deformable element freely without using glue, and its fixation in the housing hole is made by a nut partition having a hole with a diameter equal to the small diameter of the firing pin. To increase the safety of the device, the nut is designed in such a way that the striker does not protrude beyond the dimensions of the device.

In addition, in contrast to the known design, the transfer charge and the detonator block are made in the form of a separate assembly. The aluminum cap pressed on _^half the height of the cap weighed powder blasting explosives of HMX, which is a transfer charge. A detonator bomb pressed from a thermoplastic blasting explosive with a cumulative recess lined with metal foil is inserted into the aluminum cap until it contacts the transfer charge. On the other hand, the detonator block is also covered with an aluminum cap. Fixing the assembly, the transfer charge — the detonator block in the lower hole of the device case is carried out by a nut, in the partition of which a hole is made with a diameter smaller than the diameter of the aluminum cap of the detonator block.

The analysis of publicly available sources of information on the prior art did not allow to identify a technical solution identical to the declared one, on the basis of which a conclusion is made about the unknownness of the latter, i.e. compliance of the invention presented in this application with the criterion of “novelty”.

A comparative analysis of the claimed solution with known technical solutions revealed that the presented set of distinctive features is unknown to a person skilled in the art and does not follow explicitly from the prior art, on the basis of which it is concluded that the invention presented in this application meets the criterion of “inventive step”.

To explain the invention, a specific embodiment of the invention is provided below.

The drawing shows a detonating device of a mechanical fuse.

The device consists of a housing 1, containing sequentially on a single axis a stepped cylindrical hammer 2, a deformable element 4, a detonator capsule 5, an axial channel 6, a transfer charge 8 and a detonator block 10, a cumulative recess 11, and two nuts 3 and 12.

The firing pin 2 is fixed with a nut 3, screwed onto the housing 1 of the device and having a hole in the partition whose diameter is equal to the smaller diameter of the stepped firing pin 2.

Between the detonator capsule 5 and the transfer charge 8 in the housing 1 there is an axial channel 6. The transfer charge 8 and the detonator block 10 are made in a separate assembly. The aluminum cap 7 is pressed to _^half the height of the cap weighed powder blasting explosives of HMX, which is a transfer charge detonator 8. checker 10, the molded thermoplastic cumulative blasting explosives with a recess 11, lined with a metal foil 13 is inserted into the aluminum cap 7 to the contact with a transfer charge 8. The lower end of the checker-detonator 10 is placed in an aluminum cap 9. Fixing the assembly, the transfer charge 8 - checker-detonator 10 in the housing 1 is carried out by nut 12. To prevent the assembly from falling out town nut 12 provided with an opening diameter smaller than 1 mm diameter aluminum cap 9. To improve the receptivity of the transfer charge 8 to the line of fire from the blasting cap 5 through the axial passage in the bottom of a cap 6, 7 provided with an opening coaxial with the axial channel 6.

An example of a specific implementation of the claimed design of the detonating device of a mechanical fuse is a device based on blasting explosive HMX and thermoplastic blasting explosive according to TU 84-760-78, which is intended for use in a heat-resistant blasting head of cumulative perforators lowered into oil and gas wells on tubing. In this device, the firing pin 2 made of hardened steel has a stepped shape - a larger diameter over a length of 5 mm is 3.2 mm, a smaller diameter over a length of 3 mm is 2.8 mm. The detonator capsule 5 is a sample of a blasting explosive HMX with a mass of ~ 0.020 g, pressed into the upper hole of the housing 1 of the device to a density of ~ 1.6 g / cm ³ .

The hammer 2 is installed in the hole with a large diameter freely, without glue, with a radial clearance between the hammer and the hole within 0.01 ... 0.09 mm in diameter and is supported by the end part on the detonator capsule 5 through a deformable element 4 of aluminum 0.1 mm thick foil.

The striker 2 was fixed in the hole of the housing 1 by a nut 3, screwed onto the housing 1 and having a partition 0.5 ... 1 mm thick and a hole with a diameter of 2.8 ^+0.1 mm, the shoulders of the partition opening press the striker 2 tightly onto the surface of the deformable element 4. The diameter of the axial channel 6 is 5 ... 10 times smaller than the diameter of the hole in which the firing pin is installed 2. The ratio between the diameters of the hole and the axial channel 6 is determined by the extrusion pressure of the explosive through the axial channel 6. For stable detonation excitation of the blasting explosive, the extrusion pressure is tions must exceed a critical pressure (EP Unksov Engineering Theory of Plasticity -. M .: Mashgiz, 1959). A thin layer of epoxy adhesive is applied to the thread of the housing 1 of the device to the height of the nut 3, to fix the final position of the nut 3.

The diameters of the transfer charge 8 and the detonator-checkers 10 are 6 mm, heights 7 and 23 mm, respectively. The heights of the aluminum caps 7 and 9 are selected so that the transfer charge 8 and the detonator plate 10 are in close contact with each other. The transfer charge 8 of the blasting HMX explosive pressed into the aluminum cap 7 has a density of 1.5 ... 1.6 g / cm ³ , and the density of the detonator blocks 10 of the thermoplastic blasting BB according to TU 84-760-78 is 1.8 g / cm ³ .

The cumulative recess 11 of the checker-detonator 10 is lined with 0.3 mm thick copper foil 13 and is closed with an aluminum cap 9.

Assembly transfer charge - the detonator block is inserted into the lower hole of the device housing 1 and fixed with a nut 12, the diameter of the hole in the partition of the nut 12 is 6 mm.

The thread of the nut 12 is also fixed against unwinding with epoxy glue.

The device operates as follows. With a mechanical impact of a certain energy on the striker 2 installed in the opening of the housing 1 and mounted on the deformable element 4 using the shoulders of the hole of the partition of the nut 3, the striker is shifted inside the opening of the housing 1 and the impact of the striker 2 on the detonator capsule 5 through the deformable element 4. B the process of compaction of the detonator capsule 5 and the explosive flowing into the axial channel 6 leads to the formation of heating centers, as a result of which the explosive is ignited by the combustion products through the axial channel 6 and the hole in the aluminum cap 7 s ignites the transfer charge 8.

Combustion of the transfer charge 8 under conditions of a closed volume and, as a consequence, a rapid increase in pressure passes into normal detonation, which is transmitted to the detonator 10.

The checker-detonator 10 is triggered and the explosion energy of the checker-detonator 10 is accumulated with the help of a cumulative recess, punching a hole in the bottom of the cap 9 and passing through the axial hole of the nut 12 and the air gap causes detonation of the checker-receiver of the explosive chain of the first perforator module.

Since the step striker 2 is in a free state, the energy of mechanical shock is fully transmitted to the detonator capsule through the deformable element. As a result of this, the minimum impact energy required to actuate the detonating device is reduced. This ensures guaranteed reliability of the device by eliminating the influence of adhesive bonding in the system of the strikers - the hole of the housing used in the prototype.

The proposed detonating device of a mechanical fuse, in comparison with the best examples of similar equipment, allows it to be used as part of a heat-resistant blasting head to reliably detonate cumulative perforators lowered into oil and gas wells on tubing.

The implementation of the detonating device of a mechanical fuse as described above provides the following.

1. Improving the reliability of operation of the device with a set value of the minimum impact energy due to the exclusion of the influence of the adhesive connection of the strikers - the opening of the body.

2. The guaranteed and constant value of the impact energy of the impact of the striker on the detonator capsule.

3. The decrease in the minimum energy of the initiating mechanical impulse due to the free position of the striker.

4. Improving the reliability of the transmission of detonation from the mechanical fuse device through the air gap to the checker-receiver of the explosive chain of the first module of the perforator through the use of checker-detonator with a cumulative recess lined with metal foil.

5. Improving manufacturability and safety when assembling the device by reducing the number of assembly units and the use of the transfer charge and detonator blocks in the form of a finished assembly.

The performance and reliability of the operation of the proposed detonating mechanical fuse is confirmed experimentally on industrial samples of the product when they are tested on a K-44-II machine.

Claims (4)

1. The detonating device of a mechanical fuse, comprising a housing with a sequentially cylindrical striker, a deformable element, a detonator capsule made of blasting explosive, an axial channel, a transfer charge and a detonator block, characterized in that the cylindrical striker is made stepwise, and its fixation on the surface of the deformable element is carried out by a nut, screwed onto the device body and having a partition with a hole whose diameter is equal to a smaller diameter Tru stepped cylindrical striker. 2. Device according to claim 1, characterized in that the transfer charge and a detonator block formed as a separate complete assembly comprising a cylindrical aluminum cap pressed into it at _^half the height of sample powder blasting explosives and inserted close to the detonator of the checker- thermoplastic blasting explosive, closed from the bottom also with an aluminum cylindrical cap. 3. The device according to claim 2, characterized in that the aluminum cap with a transfer charge of blasting explosive has a bottom in the bottom, coaxial with the axial channel of the device body, and the detonator plate is made with a cumulative recess lined with metal foil. 4. The device according to claim 2, characterized in that the transfer charge assembly - the detonator block is fixed in the lower hole of the device case by a nut, in the partition of which a hole is made whose diameter is smaller than the diameter of the aluminum cap of the detonator block.