RU3407U1 - DEVICE FOR ELECTROTHERMAL DESTRUCTION OF THE NEEDLE OF MEDICAL SYRINGES - Google Patents

Abstract

1. Device for electrothermal destruction of needles of medical syringes by electroresistive heating, comprising a housing, an input socket for inserting a needle with a diameter smaller than the diameter of the needle attachment zone in the syringe, a current source, a cylindrical combustion zone located behind the input socket coaxially with it, made in the housing the length of which corresponds to the length of the largest, and the diameter to the diameter of the smallest needle to be destroyed, the first electrode module connected to the first pole of the current source and installed in the housing with the possibility of introducing into the combustion zone near its end, opposite the input socket, a second electrode module connected to the second pole of the current source and installed in the housing with the ability to enter the combustion zone with a shift along its axis relative to the first module by a distance equal to part of the length of the combustion zone, and a removable collection of residues of destructible needles located under the electrode modules, characterized in that the first electrode module comprises several electrodes configured to be inserted into different sections of the combustion, mutually offset in the direction of its axis, including the area adjacent to the inlet nest. 2. The device according to claim 1, characterized in that the second electrode module contains several electrodes made with the possibility of entering into different parts of the combustion zone, while the electrodes of each module are made in the form of teeth fixed on a common base with a thickness not exceeding half their pitch, and with heat capacity and electrical conductivity 3-5 times higher than the heat capacity of the area of the destroyed needle with a length equal to the step of the electrodes, and in the position

Description

DEVICE FOR ELECTROTHERMAL NEEDLE DESTRUCTION

The utility model is related to electromechanical technologies and is intended for use in medical institutions in order to prevent infectious infections of both patients and medical personnel as a result of the reuse of used needles and syringes.

Known devices for solving this problem, based on the method of resistive melting by passing a current through the needle that is powerful enough to heat the needle (or its individual sections) to a temperature higher than the melting temperature (US Pat. N 5091621, B23H 9/00, 1992, N 5138124 , B23H 9/00, 1993, N 5138125, B23K 11/12, 1993, etc.).

In all known devices for the implementation of this method, two electrodes are used that are installed with the possibility of introducing a needle into the combustion zone, i.e. we drive in which the needle takes when entering it into the body through the input jack of the device. In some devices of this type, electric current flows along the entire length of the needle (see, for example, US Pat. Nos. 4,877,934, B23K 11/22, 1989 and N 5300752, B23K 11/12, 1994). The main disadvantage of such devices is the low efficiency of using a current source for the destruction of needles with various geometric parameters. To achieve the current value required to melt a needle with high electrical resistance, it is necessary to have a sufficiently powerful current source, which becomes excessive when the needles with low resistance are destroyed.

The closest analogue of the proposed utility model is the device according to US patent N 4628169, B23H 9/00, 1986, comprising a housing, an input slot for introducing a needle with a diameter smaller than the diameter of the needle attachment zone in the syringe made in the housing, a current source, a cylindrical combustion zone, located behind the input socket coaxially with it, the length of which corresponds to the largest and the diameter to the diameter of the smallest needle to be destroyed, the first electrode module connected to the first pole of the current source and installed in the housing with with the possibility of introducing into the combustion zone near its end opposite the input socket, a second electrode module connected to the second pole of the current source and installed in the housing e with the possibility of entering the combustion zone with an offset equal to a part of the smallest length along its axis relative to the first module needles, and a removable collection of residues of destructible needles located under the electrode modules.

In the known device, each electrode module consists of a single electrode in the form of a flat spring. In this case, one of the electrodes is installed with the possibility of point contact with the lateral surface of the needle, and the second with the tip of the needle.

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MPK5 V23N9 / 00 V23K 11/12

Since the current flowing through the electrodes is significant, and the contact surfaces of the electrodes with the needle are small, the electrodes in the known device must have very high electrical conductivity, thermal conductivity and heat resistance. This requires the use of expensive materials (for example, a platinum-coated copper gold alloy). In addition, for a uniform and unhindered course of the destruction of the needle, it should be supplied to the interelectrode zone uniformly, with a speed depending on its geometric parameters. With almost unavoidable deviations from the optimal needle feed rate, the interelectrode gap is highly likely to clog the needle residues that are not completely burnt, which leads to a short circuit.

Thus, the utility model is aimed at solving the problem of reducing the requirements for workmanship and the material of the electrodes, as well as the requirements for reproducibility of the installation of the needle in the device and / or its movement in the process of destruction.

The technical result achieved by solving this problem is to ensure the reliability, simplicity, safety and convenience of the process of destroying the needles of medical syringes.

The problem is solved mainly due to the fact that in the device containing the housing, the input socket for inserting a needle with a diameter smaller than the diameter of the zone of attachment of the needle in the syringe, the current source, the cylindrical combustion zone located behind the input socket coaxially with it, is made in the housing, the length of which corresponds to the length of the longest, and the diameter to the diameter of the smallest needle to be destroyed, the first electrode module connected to the first pole of the current source and installed in the housing with the possibility of entering into the combustion zone in lick its end opposite the input socket, a second electrode module connected to the second pole of the current source and installed in the housing with the ability to enter the combustion zone with offset along its axis relative to the first module by a distance equal to part of the length of the combustion zone, and placed under the electrode modules a removable collection of residues of destructible needles, the first electrode module contains several electrodes made with the possibility of entering into different parts of the combustion zone, mutually mixed in the direction of its axis, including I site adjacent to the input jack.

The use of several electrodes supplied to the needle in the first electrode module, each of which interacts with only one part of the needle surface, essentially facilitates the operation mode of each electrode and reduces the risk of short circuit due to delays in removal or due to incomplete removal of the remains of the needle.

In addition, it is proposed to build a second electrode module similarly to the first, i.e. containing several electrodes made with the possibility of entering into different parts of the combustion zone from the side diametrically opposite the electrodes of the first

module. In this case, it is recommended that the electrodes of each module be made in the form of teeth fixed to the general oonation with a thickness not exceeding half of their pitch and heat capacity and electrical conductivity 3-5 times greater than the heat capacity of the area of the destroyed needle with a length equal to the electrode pitch. Due to this embodiment of the electrode modules, an additional breaking effect of the electrodes on the needle is provided, which also helps to facilitate the process of its destruction.

At the same time, several alternative embodiments of electrode modules providing such an effect are proposed.

According to a preferred embodiment, the electrode modules are made in the form of gear racks mounted to rotate around a common axis perpendicular to the lindric zone and located on its continuation.

In two other embodiments, the common bases of the electrodes of the first and second modules are made in the form of shafts located on diametrically opposite sides of the combustion zone. In one of these options, the axis of the shafts is parallel to the axis of the combustion zone, so that the electrodes are introduced into the combustion zone by counter-rotating the shafts. Each subsequent electrode in each module is deployed relative to the previous one, counting from the input socket, of the electrode around the axis of the corresponding shaft in the direction of its rotation by an angle exceeding the angular size of the combustion zone, measured from a point on the axis of the corresponding shaft.

According to another embodiment, the axis of the shafts is perpendicular to the axis of the combustion zone, and the electrode modules are made in the form of gears displaced along this axis relative to the input socket by a distance not less than the length of the largest needle. The radius of each gear exceeds the distance from its axis to the axis of the combustion zone by the value of the diameter of the needle, and they are kinematically connected with gear racks rigidly connected to the input socket, which in this embodiment is installed with the possibility of axial movement when interacting with the zone of attachment of the needle in the syringe.

A group of alternative device variants is also proposed in which one of the electrode modules, for example, the second, is fixedly mounted on the housing, i.e. fixed in the combustion zone. This embodiment simplifies the basing of the needle in the combustion zone and allows you to simplify the design of the movable elements of the device. According to one of the variants of this group, the base of the movable, for example, the first electrode module is made V-shaped, with a central peak facing the axis of the combustion zone. When using this option, the destruction of the needle occurs simultaneously in two directions, starting from the central zone of the needle.

The proposed device can also be equipped with a device for sealing an undestroyed needle residue fixed in a syringe, made in the form of opposite sealing electrodes installed in the first and second modules from the input socket side at the same distance from it

the possibility of entering the combustion zone. In this case, one or two such sealing electrodes can be placed in each electrode module. In the second case, it is recommended to perform these electrodes similarly to other electrodes, i.e. in the form of teeth with heat capacity and electrical conductivity 3-5 times higher than the heat capacity of the area of the destroyed needle, mutually offset in the direction of the axis of the combustion zone. In this case, it is advisable to connect one sealing electrode of the first module and the opposite electrode of the second module to one pole of the current source, and two other sealing electrodes to the other pole of this source.

A device variant is also provided that provides automation of the process of burning the needle. According to this embodiment, the input jack of the device is axially biased relative to its initial position inside the housing and the device is equipped with a drive for sequentially introducing the electrodes of each module into the combustion zone, a drive for outputting electrodes from this zone and a key included in the control circuit of the input drive and in the input source current and configured to close when the input jack is displaced from its original position. This eliminates the need for the operator to take any action to ensure contact of the needle with the electrodes, i.e. An additional increase in the reliability and usability of the device is achieved.

Prevention of penetration into the room of harmful vapors released as a result of decomposition of drugs contained in needles, i.e. further improving the safety of the device is ensured by the fact that the device is equipped with a fan installed in the housing connected to a power source and an air absorption filter installed at the fan inlet.

The utility model is illustrated by a drawing in which:

in FIG. 1 shows a general view of a device using a preferred embodiment of electrode modules;

in FIG. 1a is a schematic diagram of an embodiment of the device of FIG.

in FIG. 16, 1c shows the relative position of the needle and electrode modules at the stage of sealing the needle in the embodiment of the device of FIG. one;

in FIG. 2 is an alternative embodiment of electrode modules;

in FIG. 3 shows the mutual position of the needle and electrode modules in the embodiment of the device of FIG. 2 (on a larger scale);

in FIG. 4, 4a - different mutual positions of the needle and electrode modules in another alternative embodiment of the device;

in FIG. 5 is another embodiment of the electrode modules.

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fixing the needle 2 to be destroyed is a sleeve 3, with a guide channel 4, the diameter of which (at least a part of it) is smaller than the outer diameter of the zone 5 of the needle 2 fastening in the syringe 6. The sleeve 3 is mounted with the possibility of displacement inside the housing 1 along its flange in the direction of the axis of the guide channel 4. Directly behind the input socket 3.4, there is a zone for burning needles (indicated by a dotted line). This zone has the shape of a cylinder coaxial with the inlet socket, i.e. with a guide channel 4. The length L of the combustion zone 7 corresponds to the length of the largest needle to be destroyed using the device, i.e. equal to the length of the part that protrudes from the input socket 3.4, when the sleeve 3 is in the extreme position inside the housing 1. The diameter D of the combustion zone corresponds to the diameter of the smallest needle to be destroyed using the device. As can be seen from FIG. 1, the zone can be physically limited only by the input jack 3.4.

The device also has first 8-1 and second 9-1 electrode modules. In the embodiment of FIG. In a preferred embodiment of the utility model, both modules have a similar design. Each of them contains several electrodes 10-1, fixed on a common base 11, 12. The electrode pitch in this embodiment is determined by the permissible length m of the remains of the destroyed needle, approximately twice as long as this length. In this case, the number of electrodes is determined by the length L of the needle burning zone 7. For example, with L equal to 60 mm and t equal to 5 mm, it is recommended to install a total of 7 electrodes in the first module 8-1, and 6 in the second one. The electrodes of the first module are electrically connected to the first pole 13, and the electrodes of the second module to the second the pole 14 of the current source 15, which in the simplest case can be a step-down transformer connected by its primary winding to the alternating current network.

All electrodes 10-1 of both modules can be made the same: in the form of rectangular metal teeth with a thickness not exceeding half of their pitch, and with heat capacity and electrical conductivity 3-5 times greater than the heat capacity and electrical conductivity of the needle section with a length equal to the electrode pitch. Thus, the electrode modules 8-1, 9-1 are gear racks mounted on a common axis 01, perpendicular to the axis 0-0 of the combustion zone and located on its continuation. The rotation of the rails 11, 12 around the circle 01 provides the possibility of introducing the electrodes 10-1 into the combustion zone 7 from diametrically opposite sides. As can be seen from FIG. 1a, the tooth 10-1 of the first module 8-1, closest to the axis 01, is located so that when the rod 11 is rotated, it enters the combustion zone 7 near its end. In this case, the teeth 10 of the first electrode module 8-1 are offset relative to the electrodes of the second module 9-1 in the direction of the axis 0-0 of the cylindrical combustion zone 7 by half of their pitch. The rails 11, 12 are held in the position shown in FIG. 1 position (when all electrodes of both modules are removed from combustion zone 7)

- / - / by means of springs 16,.; ... performing the function of driving the output of electrodes from this zone.

On each rail 11, 12, a pair of additional electrodes 18, 19 and 20, 21, respectively, located on the side of the input socket 3, 4, can also be placed. According to their size and physical characteristics, the electrodes 18-21 can be completely similar to the electrodes 10. However, as shown in FIG. 1a, the first electrodes 19, 21 of both modules 8-1, 9-1 are expediently spring loaded. In contrast to the electrodes 10-1, the electrodes 18 - 21 are located without offset along the axis 0-0 of the combustion zone relative to the opposite electrodes of another module.

The electrodes 18-21 are a device for sealing an unbroken remainder of a needle fixed in a syringe. To perform this function, the first sealing electrode 19 of the first module 8-1 and the opposite electrode 21 of the second module 9-1 are connected to one pole of the current source 15, and two other sealing electrodes 18, 20 to the other pole of this source. Moreover, the choice of poles for connecting the first and second pairs of sealing electrodes depends on the ratio of the number of electrodes 10 in the first and second electrode modules. If these amounts are equal, then the first pair of sealing electrodes 19, 21 is connected to the first pole 13 of the source 15. If, however, (as in the embodiment shown in Fig. 1, 1a), the first module has one electrode 10-1 thicker, then a second pair of electrodes 18, 20 is connected to the first pole 13. It should be noted that, instead of two pairs of sealing electrodes 18, 20 and 19, 21, one pair of more massive electrodes can be used, the heat capacity and conductivity of which is approximately twice that of the corresponding characteristics of the electrodes 10 -1. In this case, each of the sealing electrodes is connected to the same pole of the source 15 as the other electrodes 10 of the same module.

The device also has an electromagnet 22, the core of which is connected via rods 23 to the rails 11, 12 of the electrode modules 8-1, 9-1. As will become clear from the following description, the electromagnet 22 with rods 23 performs the functions of driving the sequential input of electrodes 10-1, 18 - 21 into the combustion zone and withdrawing them from it. The control circuit of this drive, i.e. in the power supply circuit 24 of the electromagnet 22, a time relay 25 and a key 26 are included, the contact element of which is located on the axial displacement path of the input socket 3.4.

An exhaust fan 27 is installed in the housing 1 from the side opposite to the input socket 3.4, at the input of which an absorption filter 28 is installed. The working material of the filter 28 is selected from the conditions for the effective absorption of gases released during thermal decomposition of drugs introduced using needles to be destroyed . Under the needle burning area, there is a removable collection of the remains of the burned needles (tray 29).

electrodes 10-2, are shafts 30, 31 located on diametrically opposite sides of the combustion zone 7 parallel to its axis O-0. As in the embodiment of the device of FIG. 1, all the electrodes of the first module 8-2 are connected to the first pole 13 of the current source 15 (schematically depicted as a block 15), and all the electrodes of the second module 9-2 are connected to its second pole 14. Physical characteristics (electrical conductivity and heat capacity) of the electrodes 10 -2 are similar to the characteristics of the electrodes 10-1 in the previous embodiment of the device; in a similar way, the number, step and mutual displacement of the electrodes in the direction of the 0-0 axis relative to the corresponding electrode of another module are selected. From FIG. 3 it can be seen that each subsequent electrode 10-2 of the first module 8-2 is deployed relative to the previous one, counting from the input socket 3.4, the electrode of this module around the axis 02-02 of the shaft 30 by an angle a clockwise, i.e. in the direction of rotation of this shaft with the introduction of electrodes 10-2 into the combustion zone. The size of the angle of mutual reversal of the electrodes 10-2 must exceed the size of the angle Z, corresponding to the angular size of the combustion zone, measured from a point on the axis of the shaft 30.

Similarly selected and the mutual rotation of the electrodes 102 of the second module 9-2 around the axis 03-03 of the shaft 31.

In FIG. 4, 4a, another possible embodiment of the electrode modules 8, 9 and the input socket 3.4 is shown. A feature of the implementation of the input socket in this embodiment is that it is mounted on a carriage 32, mounted to move along the axis 0-0 of the combustion zone, coinciding with the axis of the guide channel 4 of the input socket. With the carriage 32, gear racks 33 are also rigidly connected, located symmetrically to the axis 0-0 of the combustion zone.

The electrode modules 8-3, 9-3 in this embodiment are gears, in which the teeth are electrodes 10-3. Modules 8-3, 9-3 are also located symmetrically to the 0-0 axis and are offset along this axis relative to the input socket 3.4 by a distance L not less than the length of the largest needle to be destroyed in this device. Gears 8-3, 9-3 have the possibility of oncoming rotation around their axles 04, which are perpendicular to the axis 0-0 of the combustion zone. The radius of each gear wheel 8-3, 9-3 exceeds the distance from its axis 04 to the axis 0-0 of the combustion zone by an amount) corresponding to the diameter of the needle 2, and these wheels are kinematically connected to the gear racks 33 by means of auxiliary gears 34 mounted on axes 04 of modules 8-3, 9-3. The embodiment of the electrode modules shown in FIG. 5 differs from the previous versions in that one of the modules, for example, the second module 9-4, made in the form of a base on which several electrodes 10-4 are installed (for example, 2), is fixed motionless on not shown in FIG. 5 to the housing 1 of the device so that the electrodes 10-4 of this module are constantly introduced into the combustion zone 7. Due to this, the fixation of the position of the destroyed needle 2 occurs using these electrodes, and

/ 3 not only the input jack, as in previous versions. The base 36 of the first electrode module 8-4 in this case can be made U-shaped, with the apex 37 facing the axis 0-0 of the combustion zone.

Another feature of the considered option is that the first module 8-4 is installed here with the possibility of not rotational, but translational movement in the direction perpendicular to the axis 0-0 of the combustion zone 7. In the first module 8-4 there are 3 electrodes 10-4, the central of which is fixed in the area of the apex 37, and the extreme ones are offset to the opposite points of the needle 2 to be destroyed.

The principle of operation of the proposed device will become apparent from the description of the operation of its preferred embodiment of FIG. 1a. The operator brings the syringe 6 with the needle 2 fixed in it, to be destroyed, to the proposed device and inserts the needle 2 into the guide channel 4 of the input socket 3.4 until the zone 5 of the needle 2 in the syringe 6 comes into contact with the sleeve 3 input jack. In this case, the main part of the needle 2 will be located inside the combustion zone 7. With the further movement of the needle 2, the input socket, under the influence of the fastening zone 5 of the needle 2, begins to shift in the flange 17 until it contacts the contact element of the key 26. The power supply circuit 24 of the electromagnet 22 closes from the current source 15, and the core of the electromagnet turns the rods 23, 12 of the first -1 and the second 9-1 electrode modules around axis 01. At the same time, the fan 27 and the time relay 25 are also started and the supply voltage is supplied to the electrodes of the first and second modules.

The movement of the first module 8-1 will stop when its electrode 10-1, which is extreme from the axis 01, enters the combustion zone 7 near its end, remote from the input socket 3.4, i.e., it rests against the needle 2 at its tip. Following this, from the diametrically opposite side, the outer electrode of the second module 9-1 will enter into the combustion zone 7 and come into contact with the needle portion 2, offset from the zone of its contact with the electrode of the first module in the direction of the axis 0-0 of the combustion zone 7 on the half-electrode 10-1 of each module. As a result, the external circuit of the source 15 will be closed, and a current will begin to flow between its poles 13, 14 through a pair of electrodes 10-1 and the portion of the needle 2 enclosed between them.

Due to the fact that the conductivity of the electrodes substantially exceeds the conductivity of the needle portion 2 located between them, the bulk of the energy released during the flow of current will be spent on heating this portion. Since its length is clearly limited by the appropriate choice of mutual displacement of the electrodes, the range of variation of its electrical resistance, depending on the characteristics of the needle being destroyed, can be reduced to 0.01 - 0.03 Ohms, which can significantly reduce the requirements for the current source 15 and thereby simplify its design and increase the efficiency of his work. The use of electrodes with high heat capacity prevents the heating of the electrodes themselves 10-1

As a result of the electrothermal heating of the needle segment between the electrodes, the remnants of the drugs or other substances that were on the needle are initially burned, i.e., they have the end portion of the needle sterilized. The vapors released during this (which may have an unpleasant odor and / or be toxic) are absorbed by the fan 2 into the absorption filter 28 and are absorbed therein.

When heating any section of the end segment of the needle to a temperature exceeding the melting temperature of its material, this section is divided into two parts. The acceleration of this process is facilitated by the breaking off effect created due to pressure on the needle from the diametrically opposite sides of the mutually displaced tooth electrodes 10-1. After separating the needle tip, the rack 11 is able to continue its rotation under the influence of the drive 22, 23, pushing the disinfected unburned residue of the tip down into the collector 29. The rotation of the rack 11 continues until the second electrode 10-1 of the first module is introduced into the combustion zone, i.e. . until it stops in the needle 2. After this, the operation of burning the area of the needle 2 is repeated. At its end, the disinfected non-burning residue of this area falls into the collector 29, the second electrode of the second module comes into contact with the needle, etc.

The described process of electrothermal burning of consecutive segments of the needle 2 continues until the first sealing electrode of one of the electrode modules enters the combustion zone 7 (in this case, it will be the electrode 21 of the second module 9-1). Initially, this electrode acts like any of the electrodes 10-1, i.e. serves to burn the needle section between it and the last electrode 10-1 of another module. After that, due to the additional rotation of the first module 8-1, the first sealing electrode 21 of this module will come into contact with the needle. Since the electrodes 19, 21 are spring loaded, their contact with the needle does not prevent further rotation of the modules 8-1, 9-1, so that as a result, all four sealing electrodes 18-21 will simultaneously contact the needle 2 (as shown in Fig. 16 )

As a result, a current begins to flow through the needle segment enclosed between the pairs 18, 20 and 19, 21 of the sealing electrodes. Due to the lack of mutual displacement of the opposite sealing electrodes, this segment will not experience any mechanical breaking off effect; therefore, its heating will occur until one of its sections is completely melted. As a result, this segment will be divided into two parts (as shown schematically in Fig. 1c) with the last non-fractured short segment of the needle adjacent to zone 5 of its attachment in the syringe being fused. This ensures reliable sealing of the contents of the syringe.

 after a time interval corresponding to the destruction of the largest needle, a time relay 25 trips the fan 2 and opens the drive control circuit 22, 23. Under the action of the spring drive 16, / acting on the gear racks And, 12, the electrodes are removed from the combustion zone and returned to the original position. In order to more thoroughly clean the air, the time relay 25 can be set to a later operation; in this case, the control circuit of the actuator 22, 23 is disabled by the key 26.

The above description shows that the operator’s participation in the operation of the device is limited only by the initial insertion of the needle into the input socket, and, unlike the prototype device, the nature of the process of electrothermal destruction of the needle does not depend on the accuracy of the operator’s actions. The use of a large number of electrodes increases the service life of the device, and significantly smaller fluctuations in the electrical and thermotechnical parameters of the destroyed segments of the needles compared to the spread of these characteristics for whole needles provide a significant reduction in energy consumption and the level of pulsed electrical noise.

Operation of the embodiment of the device of FIG. 2, 3 is almost completely similar to that described and differs from it only in the direction of rotation of the electrodes of both modules, which does not occur around the axis perpendicular to the 0-0 axis of the combustion zone 7, but around the 02-02, OZOZ axes parallel to the 0-0 axis.

The operation of the embodiment shown in FIG. 4, 4a, proceeds as follows. When translating the input socket 3.4 under the influence of the needle fastening zone 5 in the syringe, the carriage 32, rigidly connected to the input socket, provides translational movement of the gear racks 33, which, through the auxiliary gears 34, is converted into a rotation of the electrode modules 83, 9-3 around their axes 04. Due to the fact that the radii of the gears 8-3, 9-3 exceed the distance between their axles 04 and the axis 0-0 of the combustion zone 7, in the process of introducing the needle 2 into zone 7, the tip of the needle 2 rests against one of the electrodes 10-3 the first module 8-3 (this particular moment The ent is shown in Fig. 4). The needle, being in contact with this electrode, will continue to move until the first electrode 10-3 of the second module 9-3 abuts against its lateral surface and thereby stop the movement of the needle 2. At this moment, shown in FIG. 4a, current will begin to flow through the tip of the needle 2, which will lead to partial destruction and separation of the end portion of the needle. As a result, the remaining part of the needle will be able to translate, and modules 8-3 and 9-3 - the possibility of further rotation around the axes 04, after which the process of sequential destruction of the needle segments will continue. The disadvantage of this option is the need for impact on the needle in the axial direction from the operator throughout the entire process of its destruction.

The principle of operation of the embodiment of the device shown in FIG. 5, has some features. After completion of the insertion of the needle 2 into the combustion zone 7, it rests on everything (in the above example, two)

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electrode 10-4. Thereafter, by means not shown in FIG. 5 of the automatic or manual drive, the first module is lowered until its electrode 10-4, fixed in the region of the top 3 of the base 36 of this module, comes into contact with the central section of the needle 2. At this point, the current flows simultaneously through two sections of the needle 2 located on both sides of the peak 3. After the sterilization of both sections and the destruction of either of them (or the simultaneous destruction of both sections) is completed, the base 36 is lowered until it enters the combustion zone 7 of the two extreme electrodes 10 the first module, after which the simultaneous heating begins, followed by the destruction of the two end sections of the needle 2. Thus, in this embodiment, the destruction of the needle does not start from its tip, but from the middle and goes faster than in the previous versions. Obviously, this embodiment of the device may be preferable when increased demands are placed on the performance of the device. If the performance requirements are moderate and the device is intended only for the destruction of the same type of needles, the number of electrodes in the movable module can be reduced to a single central electrode when reducing the total number of electrodes to three.

In addition to those described, other modifications of the device are possible, for example, combining the features of the options already considered. In particular, not the second, but the first electrode module can be made stationary, and the direction of the electrodes of the other module in this case can be chosen not translational, but rotary. Various mechanisms, for example, pneumatic or hydraulic, can be used as input and output drive electrodes. However, in all cases, the number of electrodes in the first electrode module cannot be less than two, and in each of the options there can be one or two pairs of sealing electrodes.

Moreover, all of the listed possible device variants, as well as the variants discussed above with reference to the drawings, provide a lighter mode of operation of the electrodes, since the total energy released in the device for resistive heating of the needles is distributed to a larger number of electrodes. As a result, the requirements for the material and the quality of manufacture of the electrodes are significantly reduced, i.e., the device becomes more reliable and economical. In addition, the use of one or two additional electrodes in each electrode module from the input socket side can effectively solve the problem of sealing the syringe with the remainder of the needle. In variants of the device, providing the mixing of the electrodes relative to the fixed needle, also achieved a significant reduction in the qualifications of the operator working on the device.

Claims (11)

1. Device for electrothermal destruction of needles of medical syringes by electroresistive heating, comprising a housing, an input socket for inserting a needle with a diameter smaller than the diameter of the needle attachment zone in the syringe, a current source, a cylindrical combustion zone located behind the input socket coaxially with it, made in the housing the length of which corresponds to the length of the largest, and the diameter to the diameter of the smallest needle to be destroyed, the first electrode module connected to the first pole of the current source and installed in the housing with the possibility of introducing into the combustion zone near its end, opposite the input socket, a second electrode module connected to the second pole of the current source and installed in the housing with the ability to enter the combustion zone with a shift along its axis relative to the first module by a distance equal to part of the length of the combustion zone, and a removable collection of residues of destructible needles located under the electrode modules, characterized in that the first electrode module comprises several electrodes configured to be inserted into different sections of the combustion, mutually displaced in the direction of its axis, including the section adjacent to the inlet nest.  2. The device according to claim 1, characterized in that the second electrode module contains several electrodes made with the possibility of entering into different parts of the combustion zone, while the electrodes of each module are made in the form of teeth fixed on a common base with a thickness not exceeding half their pitch , and with heat capacity and electrical conductivity 3-5 times greater than the heat capacity of the area of the destroyed needle with a length equal to the step of the electrodes, and in the position corresponding to their entry into the cylindrical zone, the electrodes of the first module are offset no electrodes of the second module in the direction of the cylindrical zone axis by half their pitch.  3. The device according to claim 2, characterized in that the electrode modules are made in the form of gear racks mounted with the possibility of rotation around a common axis perpendicular to the axis of the cylindrical zone and located on its continuation.  4. The device according to claim 2, characterized in that the common bases of the electrodes of the first and second modules are made in the form of shafts located on diametrically opposite sides of the combustion zone parallel to its axis, while the electrodes are introduced into the combustion zone by counter-rotation of the shafts and each subsequent electrode in each module is deployed relative to the previous one, counting from the input socket, of the electrode around the axis of the corresponding shaft in the direction of its rotation by an angle exceeding the angular size of the combustion zone, measured from a point on B corresponding shaft.  5. The device according to claim 2, characterized in that the input socket is installed with the possibility of axial movement when interacting with the zone of attachment of the needle in the syringe, and the electrode modules are made in the form of gears mounted symmetrically to the axis of the combustion zone with an offset along this axis relative to the input socket by a distance not less than the length of the largest needle and with the possibility of rotation around axes perpendicular to the axis of the combustion zone, while the diameter of each gear exceeds the distance from its axis to the axis of the combustion zone by the diameter of the needle and they are kinematically connected with gear racks rigidly connected to the input socket.  6. The device according to claim 1, characterized in that the second electrode module is fixedly mounted on the housing.  7. The device according to claim 6, characterized in that the base of the first electrode module is V-shaped with a central peak facing the axis of the combustion zone.  8. The device according to any one of paragraphs. 1-4, 6 and 7, characterized in that it is equipped with a device for sealing an undestroyed needle residue fixed in a syringe, made in the form of opposite sealing electrodes installed in the first and second electrode modules from the input socket at the same distance from it with the possibility of input to the combustion zone.  9. The device according to claim 8, characterized in that each electrode module has two sealing electrodes in the form of teeth with a heat capacity and electrical conductivity 3-5 times higher than the heat capacity of the area of the destroyed needle, mutually offset in the direction of the axis of the combustion zone, one sealing electrode of the first module and the opposite sealing electrode of the second module are connected to one pole of the current source, and two other sealing electrodes to the other pole of this source.  10. The device according to any one of paragraphs. 2-4, characterized in that the input socket is made with the possibility of axial displacement relative to its initial position inside the housing and the device is equipped with a drive for sequential input of the electrodes of each module into the combustion zone, a drive for outputting electrodes from this zone and a key included in the control circuit of the input drive and into the input circuit of the current source and configured to close when the input jack is displaced from its original position. 11. The device according to claim 1, characterized in that it is equipped with an exhaust fan installed in the housing and an absorption air filter installed at the fan inlet.