RU2712669C1 - Washing-disinfecting ultrasonic device with hydrodynamic effect - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to cleaning of medical instruments from hardly soluble contaminants. Proposed device comprises housing with hinged cover and bath with bottom. Temperature sensor is installed in the side walls of the device. Device comprises at least two posts with connectors installed in bath and connected to water circuit. Device cover is equipped with two pneumatic drives connected to the control unit and conjugated with the case. Nozzles connected to the main pump outlet are arranged in the cover. On the bath there is a circulating module connected to the input of the main pump. In the bath there is a basket with cells. At bottom of bath on outer side there are ultrasonic radiators connected to unit of ultrasonic generators. In one of the side walls of the bath there is a first set of first fluid supply modules, connected by means of the first dispenser, the second dispenser, the third dispenser and the fourth dispenser respectively to the first container with washing liquid, a second vessel with a neutralizer, a third container with a softener and a fourth container with lubricant. In one of the side walls there is also the second set of the second fluid supply modules connected to the first input module of liquid supply, the second input module of liquid supply and the third input module of liquid supply.

EFFECT: broader functional capabilities of the washing device.

4 cl, 4 dwg

Description

The invention relates to the field of cleaning medical instruments of insoluble contaminants. It is also possible to use the invention in other areas, for example, in the jewelry and chemical industries, for cleaning parts and tools.

There is a known automatic washing machine and method comprising a process in which, in a first stage, a first composition is supplied to the washing water, which contains oxygen bleach, in a second stage, a solution containing an enzyme, but practically free of bleach, is fed into the washing water, and the objects are washed in the specified washing zone [GB10140013859, A47L 15/00]. The disadvantage of this method is the limited physico-chemical effects on objects, which reduces its functionality.

Known high pressure washer comprising an engine, a pump configured to be driven by an engine and having an outlet that provides a flow of fluid at a higher pressure than the pressure in the inlet, and control means connected to the engine and configured to controlling the operation of the engine to create more than one pump outlet pressure, wherein each of said more than one pump outlet pressure is associated with a desired use said machine [CA 2813880, B23S 3/00]. The disadvantage of this device is the limited physico-chemical effects on objects, which reduces its functionality.

A known machine for ultrasonic cleaning of metal cylindrical products, containing washing and rinsing baths separated by a partition, characterized in that it is equipped with a device for moving products in bathtubs in the form of guides with a perforated bottom, the walls of which can move relative to each other, and the guide in the washing bath has an arcuate shape, convex down, and the guide in the rinse bath has a rectilinear shape, and a drive wheel mounted on hell of an arcuate guideway equipped with removable blades located at an angle a to the tangent passing through the attachment point of the blade, while the radius of the convex part of the arcuate guideway is equal to the double radius of the drive wheel, and the washing bath is equipped with ultrasonic emitters, one of which is located in the center of the washing baths parallel to the horizontal plane, and the other two emitters are installed in the corners of the washing bath at an angle β to the horizontal plane, liquid heaters, a temperature sensor connected to a measuring controller and a frequency converter connected to a gear motor [RU 148364 (U1), C23G 5/04]. The disadvantages of this device are that during the washing process it is necessary to move parts, which limits their range and functionality of the device.

A washing machine for ultrasonic cleaning of round or spherical parts of a part is known, in which ultrasonic transducers are mounted in the washing baths and the parts roll directly along the radiating surfaces of the transducers. The diaphragm of ultrasonic transducers has the shape of a tray with parallel streams. Through these channels, a chain conveyor rolls workpieces through a washer. Due to the direct contact of the parts to be cleaned with the radiating surface, ultrasonic vibrations with large amplitudes are excited in the parts and complete and uniform cleaning of their outer and inner surfaces is ensured [RU 130766 (U1), C23G 5/04]. The disadvantages of this device are that during the washing process it is necessary to move parts, which limits their range and functionality of the device.

A device for cleaning and disinfection of endoscopes is known. This device relates to medical equipment and can be used to increase the efficiency and reliability of washing - cleaning by washing with a washing solution and disinfecting treatment of flexible endoscopes and other channel medical instruments, including catheters, laparoscopes, bronchoscopes, etc. products. The device for washing and disinfection of endoscopes contains a bath mounted on the cart for placing endoscopes with a drain pipe and a hydraulic system including a disinfectant solution supply system, a detergent solution supply system, a water supply system and a communication unit. The communication unit includes at least two diaphragm pumps, to the inputs of which a flexible pipe is connected - a hose for taking a working medium from the bath, while the output of one pump is equipped with one or more output flexible pipelines with connectors for connecting endoscopic channels of a smaller diameter - a passage section of one or several endoscopes, the output of the second pump is equipped with one or more output flexible pipelines with connectors for connecting endoscopic channels of a larger diameter - passage section I have one or more endoscopes. The system for supplying a disinfectant solution includes a container with a disinfectant solution, to which a pipe for supplying a disinfectant solution to the bath is connected by a pipe with a pump, and the system for supplying a washing solution includes a container with a detergent solution, to which a pipe for supplying a solution of bath solution is connected to a pipe with a metering pump a pipeline with shutoff valves with a water supply system; in addition, a drain pipe equipped with shutoff valves and a pipe under connected to a container with a disinfectant solution, which is equipped with shutoff valves [RU 182691 (U1), F61L 2/18]. The disadvantage of this device is the limited physico-chemical effects on objects, which reduces its functionality.

A device for cleaning and disinfection of endoscopes is known. This device relates to medical equipment and can be used to increase the efficiency and reliability of the disinfecting treatment of flexible endoscopes and other channel medical instruments, including catheters, laparoscopes and bronchoscopes. A device for washing and disinfecting endoscopes includes a bath for placing endoscopes, a washing and disinfecting solution supply system, including a pump, a solution heater and temperature measuring means, which are connected to the power and control unit, and connecting hoses for connecting the endoscope channels, and a washing supply system and the disinfecting solution contains a remote housing located outside the bathtub with inlet and outlet fittings on the front wall, in which a diaphragm pump with an eccentric electric drive, a solution heater, a means for measuring the temperature of the solution and a power supply and control unit, while the inlet pipe of the pump is connected to the inlet fitting, the outlet pipe of the pump is connected to the outlet fitting in the outlet channel, which is equipped with a solution heater and means for measuring the temperature of the solution [RU 175735 (U1), A61L 2/18]. The disadvantage of this device is the limited physico-chemical effects on objects, which reduces its functionality.

A device for cleaning and disinfection of endoscopes is known. This device relates to medical equipment and can be used to increase the efficiency and reliability of the disinfecting treatment of flexible endoscopes and other channel medical instruments, including catheters, laparoscopes, bronchoscopes. A device for washing and disinfection of endoscopes contains a bath for placing endoscopes, a system for supplying a washing and disinfecting solution, which includes a housing located outside the bathtub with inlet and outlet fittings on the front wall, which contains a diaphragm pump with an eccentric electric drive, a means for measuring the temperature of the solution and a unit power and control, while the inlet of the pump is connected to the inlet, the outlet of the pump is connected to the outlet and equipped with a means for measuring the tempo solution, containing a temperature sensor located on the outlet of the pump, and connected to the power supply and control unit measuring unit, a digital temperature indicator which is located on the front wall of the housing. In addition, the supply system of the washing and disinfecting solution is equipped with a means of protection against pressure increase, which is made in the form of a tee, one nozzle of which is connected by a connecting hose to the outlet fitting, a self-destructing plug is installed on the second nozzle - a cap that jumps off the nozzle with increasing pressure, and to the third nozzle connect the processed channel of the endoscope [RU 174014 (U1), F61L 2/18]. The disadvantage of this device is the limited physico-chemical effects on objects, which reduces its functionality.

A known method of cleaning dishes from insoluble contaminants and a device for its implementation. The invention relates to the field of cleaning dishes, in particular pharmacy, from insoluble contaminants. The purpose of the invention is to increase the operational reliability of the device by increasing the washing efficiency by expanding technological capabilities. This goal is achieved by the fact that in the method of cleaning dishes from insoluble impurities oriented downward, the inner and outer surfaces of the dishes are treated with jets of detergents for circulating and clean water under pressure. The consumption of detergents through the dishes is set so that the entire volume of the dishes (for example, the bottle) is filled with washing solution, air is removed and ultrasonic treatment is performed on the inner surface of the dishes using an ultrasonic vibrator. Moreover, the dishwashing cleaning device comprises a washing chamber with a tank, a main circulation pump, an external washing manifold with jet nozzles, an internal washing manifold with injection tubes having supports for the neck of the dishes. New in the device is the presence of an additional circulation pump connected to the collector of the internal sink, and an ultrasonic whistle, for example, a knife-type, is mounted in the injection tubes, cone-shaped diffusers are installed on the injection tubes with the possibility of height adjustment relative to the supports, as well as drainage tubes. Ultrasonic processing in a stream allows the cleaning of dishes with difficult soluble contaminants, with high quality washing to reduce energy and water consumption, eliminates intermediate loading and loading operations, and the washing process itself can be easily automated [RU 2136579, V08V 9/20]. The disadvantage of this device and method is highly specialized means of placing objects, which reduces the functional capabilities of the invention.

A device is known for pumping liquid for washing and disinfecting the channels of endoscopes and other channel medical instruments and products, containing an electric pump and a power supply and control unit installed in the housing, to which a pump electric drive is connected, while the pump inlet and outlet nozzles and pump electric drive controls mounted on the front wall of the housing, characterized in that the pump is made in the form of a diaphragm pump with an eccentric electric drive, while the outlet pipe of the pump is equipped with n means for measuring the temperature of the liquid being pumped. There is an option in which the means for measuring the temperature of the pumped liquid contains a temperature sensor located on the outlet of the pump, and a measuring unit connected to a power and control unit, a digital temperature indicator of which is located on the front wall of the housing. There is an option in which the device is equipped with a timer that sets the operating time interval of the diaphragm pump connected to the power and control unit, the control elements of which and the digital indicator of the time interval are located on the front wall of the housing. There is an option in which the diaphragm pump is provided with a means of protection against increasing pressure. There is an option in which the protection against pressure increase is made in the form of a tee, one pipe of which is connected to the pump outlet pipe, a self-destructing cap-cap is installed on the second pipe, which jumps off the pipe when the pressure is increased, and the channel being machined is connected to the third pipe [RU 164385 (U1), A61L 2/18]. The disadvantage of this device is the limited physico-chemical effects on objects, which reduces its functionality.

A known method of cleaning, disinfection and sterilization of medical instruments containing extended channels, mainly endoscopes and dental handpieces, in which the processed medical instruments are placed in a chamber filled with an electrically conductive medium, and is subjected to an indirect electric current that is applied to electrodes previously placed in the chamber and connected to a power source without conductive contact of medical instruments with electrodes, characterized in that for uschestvleniya intensive indirect effects of electric shock on their medical instruments are arranged in the vicinity of the electrodes: at least one of the anode and the cathode, wherein the electric shock exposure is performed under condition of generation of micro plasma discharges simultaneously on all electrodes. There is an option in which, for cleaning and sterilizing medical instruments containing channels, an electrically conductive medium is additionally circulated through the channels of the instrument. There is an option in which for the cyclic effect of the electrically conductive medium on the medical instrument being processed, its pulsating supply is carried out. There is an option in which to intensify the cleaning and sterilization process, an electrically conductive medium is circulated, which is additionally activated by microplasma discharges in at least one additional microplasma chamber [RU 2527326, АВВ 90/70]. The disadvantage of this device is the complexity of the method and device using a plasma discharge, as well as the complexity of the operation of the device associated with the individual installation of medical instruments.

A device for cleaning and disinfection of endoscopes is known. This device relates to medical equipment and can be used to increase the efficiency and reliability of the disinfecting treatment of flexible endoscopes and other channel medical instruments. The device comprises a bath for placement of endoscopes, a supply system of a washing and disinfecting solution, including a pump, a solution heater and means for measuring temperature, which are connected to the power supply and control unit, and connecting hoses for connecting the channels of the endoscope, the washing and disinfecting solution supply system comprising outside the bathtub, a remote housing with inlet and outlet fittings on the front wall, in which a diaphragm pump with an eccentric electric drive is located, a heater create, means for measuring the temperature of the solution and the power supply and control, the pump inlet pipe is connected to the inlet, the outlet of the pump connected to the outlet nipple outlet passage, which is provided with a heater solution and means for measuring the temperature of the solution. The result is an increase in the efficiency and reliability of washing and disinfection [RU 2654704, A61L 2/18]. The disadvantage of this device is the limited physico-chemical effects on objects, which reduces its functionality.

This device is selected as a prototype of the proposed solution.

The objective of the invention is to create a multifunctional washer.

The technical result of the invention is to expand its functionality.

The specified technical result is achieved in that in a washing and disinfecting ultrasonic device with hydrodynamic effects, comprising a body with a hinged lid, comprising a first section in which a bath with a bottom, first side walls and second side walls is installed, in which a temperature sensor is installed, which also contains at least two racks with connectors installed in the bath and connected to the water path, including the main pump and the flow heater, and connected to the control unit, to The tower is equipped with two pneumatic actuators connected to the control unit and interfaced with the body, nozzles connected to the output of the main pump are located in the lid, a circulation module is installed on the bath, connected to the main pump inlet, a basket with cells is located in the bath, on the outside of the bath ultrasonic emitters are connected, connected to the block of ultrasonic generators, in one of the side walls of the bath there is a first set of first fluid supply modules connected via the first dispenser a, a second dispenser, a third dispenser and a fourth dispenser, respectively, to the first tank with washing liquid, the second tank with a neutralizer, the third tank with a softener and the fourth tank with lubricant, in one of the side walls there is also a second set of second fluid supply modules connected to the first the input fluid supply module, the second input fluid supply module and the third input fluid supply module. There is an option in which the water path includes a bath connected through the circulation module to the input of the main pump, the output of which is connected through a flow heater to a collector connected to the racks and nozzles of the cover, while the drain path also includes a drain module mounted on bottom of the bath.

There is also an option in which the housing includes a second section, a third section and a fourth section, while in the second section there is a block of ultrasonic generators and a control unit, in the third section there are a first tank with washing liquid, a second tank with a neutralizer, a third tank with a softener and the fourth tank is lubricated, and in the fourth section there is a main pump with a flow heater and a collector, as well as a first dispenser, a second dispenser, a third dispenser and a fourth dispenser. There is also an option in which four racks with connectors are installed at the corners of the bathtub.

In FIG. 1 shows a washing and disinfecting ultrasonic device with a hydrodynamic effect, side view.

In FIG. 2 shows a washing and disinfecting ultrasonic device with hydrodynamic effects, a top view.

In FIG. 3 shows a washing and disinfecting ultrasonic device with hydrodynamic effects, section B-B.

In FIG. 4 shows a structural hydraulic diagram of a washing and disinfecting ultrasonic device with hydrodynamic effects.

The hydrodynamic washing and disinfecting ultrasonic device includes a housing 1 (FIG. 1, FIG. 2, FIG. 3) divided into a first section 2, a second section 3, a third section 4, and a fourth section 5. A hinged cover 6 is mounted on the housing 1 with two pneumatic actuators 7. A set of nozzles 8 is located in the hinged lid 6. In one embodiment, eight nozzles 8 can be used uniformly installed over the area of the hinged lid 6. In the first section 2, a bath 9 with a bottom 10, the first side walls 11 and the second side is installed walls 12, vypo nennaya, for example, steel 08H17N13M2. The bath 9 can be installed in the first section 2 by means of struts (not shown) with support on its bottom or with support on the side walls (also not shown). The dimensions of the bath 9 can be in the ranges: length from 500 mm to 1500 mm, width from 200 mm to 800 mm, height from 200 mm to 500 mm. In the bath 9 there is a basket 13 made, for example, of stainless wire (for example, also 08X17H13M2) with cells measuring 5-15 mm. Cell size may vary depending on the tools being processed. The cells in FIG. 1 and FIG. 2 conventionally not shown. Another form of cells can be used, and another way of their formation, for example, by cutting in a thin (1.0-2.5 mm) stainless steel sheet. The basket 13 may have four holes 14 in the corners. The basket 13 can be installed in the bath 9 by means of struts (not shown) with support on the bottom 10 or with support on the side walls 12, 13 (also not shown). At least two racks 15 with quick connectors 16 can be installed in the corners of the bath 9. The best option is to use four racks 15 with six quick connectors 16 on each rack. The number of quick connectors 16 may be different. Racks 15 are geometrically interfaced with holes 14. The size of the holes 14 should allow the basket 13 to be freely removed bypassing the racks 15 with quick connectors 16. In one of the side walls, for example 12, there is a first set of first fluid supply modules 17 and a second set of second fluid supply modules 18 . The arrangement of the first fluid supply modules 17 and the second fluid supply modules 18 (on one side wall or on different side walls) may be different from that shown in FIG. 1. At the bottom 10 of bath 9, a drain module 19 is installed (including a drain hole protected by a strainer, a drain valve and a drain pump (not shown)). The shape of the bottom 10 of the bath 9 and the inclination angles of all drain pipelines (not shown) are made so that under the influence of gravitational forces with the drain valve turned off, no liquid remains in the bath 9 and drain pipelines. At the bottom 10, on the outside of the bath 9, ultrasonic emitters 20 are fixed, for example, by means of an adhesive joint 21. Piezoelectric transducers PP1-0.75 / 25 can be used as ultrasonic emitters 20. As the adhesive, an adhesive composition based on epoxy resin with a titanium filler can be used. The thickness of the adhesive joint 21 may be in the range of 1 mm to 3 mm. Inside the bath 9, a dual temperature sensor 22 is installed, for example, based on the thermal resistance of Pt100. A circulation module 23 is connected to the bath 9, including a fitting and a valve (not shown). In the second section 3, a control unit 25 and a block of ultrasonic generators 26 can be located. In the third section 4, a first tank 28 with washing liquid, a second tank 29 with a neutralizer, a third tank 30 with a softener and a fourth tank 31 with lubricant can be installed. As a washing liquid, 3E-ZYME Medisase UK Ltd liquid can be used, as a neutralizing agent - an ultra concentrate Neutral cleaner Prolystica from Steris, as a softener - a means for neutralizing and descaling Steris from a Steris, as a lubricant - an ultra concentrate Lubricant Prolystica from Steris . A sampling device 32 with a level sensor 33 is installed on each tank. In the fourth section 5 (Fig. 3), a main pump 35 with a flow heater 36 and a collector 37 is installed. In this case, the main pump 35 is connected with its input to the circulation module 23 (Fig. 4) and the outlet - with nozzles 8. As the main pump 35, you can use the pump H-HS-HW-HSW company Ebara. As a flow heater, you can use a pipe with a heating element (TEN) with built-in thermal protection. On the manifold 37, for example, four first dispensing valves 38 and a second dispensing valve 39 are installed. In the fourth section 5, a first dispenser 40, a second dispenser 41, a third dispenser 42 and a fourth dispenser 43 are also installed (each dispenser includes a metering pump and a flow meter, not shown ) As a metering pump, you can use a pulse pump type ETS 17-P / C company Gotec. On the housing 1, a first input fluid supply module 45, a second input fluid supply module 46, and a third input fluid supply module 47 are located (each input module includes a fitting, a valve, and a pipe for supplying fluid to the bath 9 (not shown)). The input modules of the fluid supply are used to supply the bath 9 from external sources of cold water, hot water and purified water. The water path includes a bath 9, connected through the circulation module 23 to the input of the main pump 35, the output of which is connected through a flow heater 36 to a collector 37 connected to the racks 15 and nozzles 8 of the cover 6, while the drain path also includes a drain module 19 mounted on the bottom 10 of the bath 9.

Bath 9 may be coupled to a level sensor 50, which is a container 51, in which is located a block of sensors for the presence of liquid 52, for example, DP01-NO-NPN-PC4.

Pneumatic actuator 7, drain module 19, dual temperature sensor 22, circulation module 23, block of ultrasonic generators 26, main pump 35, flow heater 36, first control valves 38, second control valve 39, first dispenser 40, second dispenser 41, third dispenser 42 , the fourth dispenser 43, the first input fluid supply module 45, the second input fluid supply module 46, the third input fluid supply module 47 and the level sensor 50 are connected to the control unit 25.

Ultrasonic emitters 20 are connected to the block of ultrasonic generators 26.

On the outside of the housing 1 is a panel 55 connected to the control unit 25 and designed to operate the device and input / output information.

The fact that the cover is equipped with two pneumatic actuators connected to the control unit and interfaced with the body, the nozzles are connected to the output of the main pump in the cover, a circulation module is installed on the bath, connected to the main pump inlet, a basket with cells is located in the bath, at the bottom of the bath ultrasonic emitters are connected from the outside, connected to the block of ultrasonic generators, in one of the side walls of the bath there is a first set of the first fluid supply modules connected via the first a dispenser, a second dispenser, a third dispenser and a fourth dispenser, respectively, to the first tank with washing liquid, the second tank with a neutralizer, the third tank with a softener and the fourth tank with lubricant, in one of the side walls there is also a second set of second fluid supply modules connected to the first the input fluid supply module, the second input fluid supply module and the third input fluid supply module expands the functionality of the device due to the possibility of processing more widely th range of products. The fact that the water path includes a bath connected through the circulation module to the inlet of the main pump, the output of which is connected through a flow heater to a collector connected to the racks and nozzles of the lid, while the drain path also includes a drain module mounted on the bottom of the bath , expands the functionality of the device due to the possibility of processing a wider range of products.

The case includes a second section, a third section and a fourth section, while in the second section there is a block of ultrasonic generators and a control unit, in the third section there are a first tank with washing liquid, a second tank with a neutralizer, a third tank with a softener and a fourth tank with lubricated, and in the fourth section there is a main pump with a flow heater and a collector, as well as a first dispenser, a second dispenser, a third dispenser and a fourth dispenser, simplifies the operation of the device.

The fact that four racks with connectors are installed at the corners of the bath, expands the functionality of the device due to the possibility of simultaneous processing of a medical instrument, as well as special devices containing extended channels, for example, endoscopes.

Washing and disinfecting ultrasonic device with hydrodynamic effects is as follows.

A medical tool is placed in basket 13. Endoscopes, for example, are worn on quick-release valves 15 of racks 16. The operator from the control panel 55 (Fig. 2) pre-selects the desired program and starts the device from the control panel 55. The lid 6 (Fig. 1) is closed by means of pneumatic actuators 7. Through the input fluid supply modules 45, 46, 47 and the second supply modules liquid 18, bath 9 is filled. The liquid level at all stages is monitored by a level sensor 50, the temperature is monitored at all stages by a dual temperature sensor 22. Upon reaching the level set by the program and the set temperature, the program starts cycle stage, in the strict sequence: preliminary washing (20 ° С-45 ° С), main washing (20 ° С-65 ° С) with hydrodynamic action, ultrasonic washing with alternating frequencies, rinsing with cold water, rinsing with hot water, thermal disinfection (75 ° С-95 ° С), cooling or drying. At each stage, it is possible to supply into the bath with the dispensers 40, 41, 42, 43, previously set in the program, the volume of working fluids from the containers 28, 29, 30 and 31 by means of the corresponding intake devices 32 through the first fluid supply modules 17. Hydrodynamic action is provided, pressure of at least 3 Bar created by the main pump 35 in the water path through nozzles 8 and racks 15. Heating of the liquid to the temperature specified in the program, in each of the stages of the cycle, is provided by the flow heater 36 when the liquid circulates through the water path. The temperature control is provided by the control unit 25 using a dual temperature sensor 22. The ultrasonic washing stage is activated by the control unit 25, which includes a block of ultrasonic generators 26, which generates ultrasonic pulses at frequencies of 25-75 kHz and feeds them to the ultrasonic emitters 20. The control unit 25 controls the operating time of the block of generators 26, the frequency specified in the program and its alternation. The time of each washing stage can be in the range of 1 min - 60 min.

The parameters of each stage are displayed on the control panel 55 and logged in the memory of the control unit 25. The complete cycle protocol is available as a text file and can be saved directly by the user to an external medium via the USB port of the control panel 55 or transferred from the network via the request (ithernet, WI -FI) remotely. Data transmitted over the network can be integrated into a single sterilization process control network and instrument turnover control system.

Claims (4)

1. A washing and disinfecting ultrasonic device with hydrodynamic effects, comprising a body with a hinged lid, comprising a first section in which a bath with a bottom, first side walls and second side walls is installed, in which a temperature sensor is installed, which also contains at least two racks with connectors installed in the bath and connected to the water path, including the main pump and the flow heater and connected to the control unit, characterized in that the cover is equipped with two pneumatic actuators and nozzles connected to the output of the main pump are located in the lid, connected to the control unit and paired with the body, a circulation module is installed on the bath, connected to the main pump inlet, a basket with cells is located in the bath, ultrasonic emitters are fixed on the bottom of the bath, connected to the block of ultrasonic generators, in one of the side walls of the bath there is a first set of first modules for supplying liquids connected via a first dispenser, a second dispenser, and a third dispenser and the fourth dispenser, respectively, to the first tank with washing liquid, the second tank with a neutralizer, the third tank with a softener and the fourth tank with lubricant, in one of the side walls there is also a second set of second fluid supply modules connected to the first input fluid supply module, the second input a fluid supply module and a third input fluid supply module. 2. The device according to p. 1, characterized in that the water path includes a bath connected through a circulation module to the input of the main pump, the output of which is connected through a flow heater to a collector connected to the racks and nozzles of the cover, while the drain path includes also a drain module installed at the bottom of the bath. 3. The device according to p. 1, characterized in that the housing includes a second section, a third section and a fourth section, while in the second section there are a block of ultrasonic generators and a control unit, in the third section there is a first tank with washing liquid, a second tank with a neutralizer , a third tank with a softener and a fourth tank with lubricant, and in the fourth section there is a main pump with a flow heater and a collector, as well as a first batcher, a second batcher, a third batcher and a fourth batcher. 4. The device according to claim 1, characterized in that four racks with connectors are installed at the corners of the bath.

Images