PL241386B1 - Mobile sanitation device - Google Patents

Abstract

A mobile sanitation device consisting of a working chamber (A) and a use chamber (B) which consists of at least one sanitation chamber (11). In the working chamber (A) there is an inlet pipeline (1) to which a buffer tank is connected, fed by a saturation pipeline (13) equipped with a pump (4), an injector (5) and a cooler (7) in the sequence of flow. The injector (5) is connected to the micro-nano bubble generator (14) by means of the supply pipe (6). The cooler (7) is connected with the cooling pipe (16) to the cooling source (8). In the sanitation chamber (11) there is a set of mist nozzles (10), the outlet of which is positioned perpendicular to the sanitization chamber ceiling (11). The mist nozzles (10) are arranged on a rectangular plan, with the outlet directed downwards and located below the area of air suction by the air curtains. The condensate discharge pipeline (12) is connected to a drain located at the bottom of the sanitation chamber (11), which is equipped with two pairs of doors located opposite each other on both sides of the sanitation chamber (11). There are air curtains inside the chamber directly above the door.

Description

The subject of the invention is a mobile sanitation device for sanitizing people, animals and things.

The invention relates to the field of sanitation devices.

The largest group of devices and installations described in the known art are methods of cleaning and disinfecting both food products and mechanical elements.

From the state of the art, in the application P.339515 "Method for cleaning and disinfecting medical devices by K. Dish and K.P. Bansemir describe a method of cleaning and disinfection based on immersing medical instruments in a special solution with disinfecting properties. Similarly, in the application P.312786 "Method of washing and disinfecting eggs by A.J. Harvey, J.W. Malone and W.R. Senderson present the method of using water solutions for washing and disinfecting eggs. Many inventors use various cleaning agents in their solutions: from water with additives to various types of disinfecting, disinfecting and deratising agents in the form of liquids and gases. The devices are available in both stationary and portable or mobile versions.

In the application P.394859 "Mobile water disinfection and pumping station" J. Jonkisz and J. Szuta present a mobile device equipped with a pumping, filtration and dosing system of various chemicals into tap water, and in the application P.426192 "Disinfection method of operating theaters in hospitals with O3 ozone ”I. Leja presents a method of using pure ozone in gaseous form to disinfect operating room surfaces.

In the known art, comprehensive solutions that are both methods and devices for carrying out this method have also been submitted for protection. In the application P.401820 "System and method of disinfection and deodorization of waste collection systems using ozone" C. Rolandas, K. Vytas, K. Saulius and B. Velarij present a solution using ozone in the form of gas to minimize the negative impact of bacteria in waste collection systems. There are also known methods of saturating water with micro-blisters, nano-blisters or micro-nano blisters of various gases. R.J. Agranonik and G.A. Pisklov in the application RU 94030202 "Method for saturation of liquid with gas" describe the method of saturating the liquid intended for the gas flotation process. In their solution, they use a thermocompressor to reduce energy consumption. P.S. Wiidley in the application WO2013017935 "Device and method for saturating liquid with gas" describes a method of aerating liquids using a device for crossing accelerated streams of liquid in a gas atmosphere. B.A.O. Sulejmanov, in the application EA030820 "Method for production of nanofluid with gas nano-bubbles" describes a method of producing a liquid saturated with gas by carrying out a process under pressure.

Devices and methods for producing micro-nano blisters are also known in the art. B. J. Vinci, B. J. Watten, M. B. Timmons, Modeling gas transfer in a spray tower oxygen absorber, Aquacultural Engineering, Volume 16, Issues 1-2 pp. 91-105, 1997 show the use of spray nozzles to spray water in a column to which it is supplied oxygen thus creating water saturated with gas. R. Etchepare, H. Oliveira, M. Nicknig, A. Azevedo, J. Rubio Nanobubbles: Generation using a multiphase pump, properties and features in flotation, Minerals Engineering, 2017 (Volume 112), pp. 19-26 present a solution using a saturation pump to create a pressurized water-air mixture, then expand it in order to obtain nano air bubbles. This solution is based on the suction of air under atmospheric pressure and mixing it with water in liquid form.

There are no known systems, however, that in one mobile device combine sanitization with the use of water mist saturated with micro-nano blisters of ozone, internally protected against the development of bacteria and viruses with the use of copper panels and using air curtains to maintain water mist saturated with micro-nano bubbles inside the system, intensify the flow of water mist inside and cleaning the moistened surfaces from excess moisture, allowing the free passage of other people.

The aim of the invention is a mobile, quickly and easily transportable and very effective device, the purpose of which is to effectively sanitize passersby who enter public facilities (shopping centers, cinemas, theaters, offices, etc.).

The proposed solution consists in generating water saturated with micro-nano ozone bubbles with a diameter significantly less than 0.1 mm, which is then distributed in the form of a generated cool water mist fed between the air curtains, so that falling by gravity, being entrained by the air flow from the air curtains, sanitizes passing people.

PL 241 386 B1

Maintaining the free fall of fog and preventing its spread has been guaranteed by air curtains separating the outside atmosphere from the inside, while keeping the necessary amount of fog in the chamber, regardless of the number of people passing by. The chamber through which people pass can be additionally lined with a copper sheet, which has a disinfecting effect, reducing the need for disinfecting the chamber itself and enabling maintenance-free operation immediately after setting up the device. Bursting micro-nano blisters generate ultrasound waves that cleanse all solid surfaces, i.e. surfaces that will be in contact with water mist. As a result of cracking micro-nano blisters, hydroxyl radicals OH * are formed, which are very strong oxidants, which, in combination with ozone, which is a disinfectant 3000 times stronger than chlorine, will lead to full sanitization of clothes and skin of people passing by in a very short time. Hydroxyl radicals destroy all microorganisms such as bacteria or viruses and have an impact on already embedded microbial contamination. A key area is also the use of water mist generating nozzles using water saturated with micro-nano ozone bubbles, because only the water mist distributes a small amount of water containing ozone and micro-nano ozone bubbles simultaneously filling the entire volume of the sanitation chamber. This ensures an optimal concentration of micro-nano ozone bubbles in the entire volume and replenishment of the used fog in real time.

The sanitation chamber is designed in such a way as to create a microclimate inside it of a high concentration of water mist saturated with micro-nano ozone blisters, allowing the sanitization of the external surfaces of the covering of people passing through it.

The sanitation device according to the invention uses water mist saturated with micro-nano bubbles, consisting of a working chamber in which water saturated with the maximum possible amount of micro-nano bubbles is produced, and a usable chamber in which, by means of mist nozzles, water mist containing micro-nano ozone bubbles, kept inside the chamber by the action of air curtains installed above the chamber entrance and exit. Only this configuration of the system makes it possible to ensure, on the one hand, that the chamber is filled with micronano-saturated mist with ozone bubbles in its entire volume, as well as drying the clothes of people coming out of the excess deposited and used water mist, leaving the clothes surfaces dry for people leaving.

The essence of the invention is a mobile sanitation device consisting of a working chamber and a service chamber, which consists of at least one sanitation chamber. In the working chamber there is an inlet pipeline with a feed water pump to which a buffer tank is connected, fed by a saturating pipeline, the inlet of which is at the bottom of the buffer tank and the outlet of which is at the top of the buffer tank. The saturation pipeline is equipped with a pump, an injector and a cooler in the sequence of flow. The injector is connected to the micro-nano bladder generator by means of a supply pipeline. The cooler is connected to the cooling source by means of a cooling pipeline consisting of a supply pipeline and a return pipeline. In the sanitation chamber there is a set of fog nozzles, the outlet of which is positioned perpendicular to the ceiling of the sanitation chamber, the outlet of which is at least 230 cm above the sanitization chamber floor. The mist nozzles are set on a rectangular plan with dimensions equal to the width of the sanitation chamber - in relation to the door - and ~ 75 cm long with the outlet pointing downwards and located below the air intake area through the air curtains. The mist nozzles are connected by means of a spraying pipeline, the inlet of which is located in the buffer tank, which pipeline is equipped with a spraying pump. The condensate discharge pipeline is connected to a drain located at the bottom of the sanitation chamber, which is equipped with two pairs of doors facing each other. On both sides of the sanitation chamber, directly above the door, inside the chamber, there are air curtains supplied with air from the inside of the spraying space, sucked in from the space between the top of the sanitation chamber and the outlet of the mist nozzles. The air curtains have an air supply width that corresponds to the width of the sanitation chamber.

Preferably, the inside of the sanitation chamber is lined with copper panels.

The invention has been illustrated in the drawings, where Fig. 1 shows a block layout of a sanitation device, Fig. 2 shows a block diagram of a sanitation chamber, Fig. 3 shows a simulated view of the circulation of a sanitation mist, Fig. 4 shows a visualization of the sanitation device in a preferred embodiment.

PL 241 386 B1

The invention, in a preferred embodiment, has been implemented with the use of a sea container with dimensions of ~ 600 cm in length, ~ 245 cm in width and ~ 260 cm in height. Two chambers have been separated in the container: working A, dimensions: ~ 350 cm long, ~ 245 cm wide and 260 cm high, and utility B, ~ 250 cm long, ~ 245 cm wide and ~ 260 cm high. Inside the working chamber A there is a water supply from the municipal water system through the inlet pipeline made of PVC with a diameter of 1/2 1, on which a centrifugal feed water pump 2 with an output of 78 l / h has been installed. The pump located in this place is designed to initially increase the pressure in the circuit. The inlet pipeline 1 is connected to the buffer tank 3 with a capacity of 25 liters made of 316L stainless steel. The buffer tank 3) is connected to the inlet and outlet of the saturation pipeline 13 made of 316L stainless steel with a diameter of 1/2, the inlet of which is at the bottom of the buffer tank 3 and the outlet is at the top of the buffer tank 3. The saturation line 13 is equipped with , in the sequence of liquid flow into a centrifugal pump 4 with an output of 5 ^m3 / h and a head from 3 bar to 6 bar, an injector 5 with a pressure drop of 2 bar and a cooler 7 enabling the cooling of water to a temperature not exceeding 20 ° C. The injector 5 is connected to the micro-nano bladder generator 14 with a capacity of 20 g O3 / h, fed with ozone with a concentration of 8%, by means of the supply pipeline 6. The cooler 7 is supplied with the refrigerant produced in the cooling source 8, which is a compressor unit with a cooling capacity of 1, 8 kW using R134 refrigerant with refrigerant piping 16 consisting of refrigerant supply piping 16a and refrigerant return piping 16b. Lowering the temperature of the water is very important for the process in two ways. Firstly, it allows to obtain a higher ozone saturation of the water, up to 27.5 mg / l for the temperature of 20 ° C, compared to the achievable value of 11.5 mg / l for the temperature of 40 ° C, which is only achieved without cooling. Secondly, when sprinkled, it has a cooling effect, especially important in summer or in countries with hot climates.

Inside the utility chamber B, two sanitation chambers 11 are separated, in each of the sanitation chambers 11 there is a set of 30 fog nozzles 10 attached to a steel grate, attached with screws to the ceiling of the sanitation chamber 11, spaced on a rectangular plan, 120 cm wide by 73 cm. , 5 cm long (evenly spaced in a 6x5 matrix) connected to the buffer tank 3 with a spraying pipeline 15 with a diameter of 1/2, made of PVC, which is equipped with two spray pumps 9 with a total output of 78l / h - one pump for each sanitation chamber. Thanks to the use of mist nozzles, water saturated with micronized ozone bubbles is sprayed with droplets of less than 80 μm, whose free falling speed guarantees that the mist remains in the sanitation chamber 11 for at least 16 seconds. B of the usable condensate discharge pipeline 12 made of PVC with a diameter of 1/2.

In the sanitation chamber 11 there is a microclimate of high concentration of water mist saturated with micro-nano ozone bubbles, allowing sanitization of people passing through it.

In order to ensure an even distribution of water mist throughout the sanitation chamber 11 and to ensure that it does not spread beyond the sanitation chamber 11, the inlets / outlets 11.2, 11.6 from the chamber, 90 cm wide and 207 cm high each, were equipped with an automatic door with a passage width of 90 cm. and a passage height of 207 cm and air curtains 11.1.1 1.5 with an air supply width of 120 cm and an air flow rate of 1700 m ³ / h, which gives an air supply speed of about 11 m / s. An additional purpose of the air curtains 11.1, 11.5 is drying the remaining water particles that may remain on the outer garments after sanitation.

Part of the sanitation chamber 11, which is a spray chamber 11.4, 230 cm long by 120 cm wide by 245 cm high, was lined with copper (walls and ceiling), the antiseptic properties of which are commonly known and used in combination with water mist partially condensing on the walls ensures their full sanitation. In combination with ozonated water, micro-nano blisters in the spray chamber create a microclimate that effectively sanitizes people walking inside. In the upper part of the spray chamber 11.4, at a height of 230 cm from the bottom of the chamber, a set of mist nozzles 11.4 is installed, the outlet of which is located above the lower part of the air curtains 11.1, 11.5.

The whole was installed in a sea-type shipping container, enabling its very easy transport, set-up and quick launch

Claims (2)

1. Mobile sanitation device characterized by the fact that it consists of a working chamber (A) and a usable chamber (B) which consists of at least one sanitation chamber (11), where in the working chamber (A) there is an inlet pipe (1) with a feed water pump (2) to which the buffer tank (3) is connected, fed by a saturation pipeline (13) whose inlet is at the bottom of the buffer tank (3) and whose outlet is at the top of the buffer tank (3); the saturation pipeline (13) is equipped, in the order of flow, with a pump (4), an injector (5) and a cooler (7); the injector (5) is connected to a micro-nano bubble generator (14) by means of a supply pipe (6); the cooler (7) is connected by means of a cooling pipeline (16) consisting of a supply pipeline (16a) and a return pipeline (16b) to the cooling source (8); in the sanitation chamber (11) there is a set of fog nozzles (10), the outlet of which is positioned perpendicular to the ceiling of the sanitation chamber (11), the outlet of which is at least 230 cm above the floor of the sanitation chamber (11), fog nozzles (10) are set are on a rectangular plan with dimensions equal to the width of the sanitation chamber (11) - in relation to the door (11.2, 11.6) and length ~ 75 cm with the outlet directed downwards and located below the air suction area through the air curtains (11.1, 11.5), fog nozzles (10 ) are connected by a spraying pipe (15), the inlet of which is in the buffer tank (3), which pipe (15) is equipped with a spraying pump (9); the condensate discharge pipeline (12) is connected to the outlet (11.3) located at the bottom of the sanitation chamber (11), which is equipped with two pairs of doors (11.2, 11.6) located opposite each other on both sides of the sanitation chamber (11), directly above the door (11.2, 11.6), inside the chamber there are air curtains (11.1, 11.5) supplied with air from inside the spraying space (11.4), sucked in from the space between the top of the sanitation chamber (11) and the outlet of the mist nozzles (10); air curtains (11.1, 11.5) have an air supply width that corresponds to the width of the sanitation chamber (11). 2. The device according to claim The device of claim 1, characterized in that the interior of the sanitation chamber (11) is lined with copper panels.