BG113228A - UV DISINFECTION ROBOT - Google Patents

Abstract

The UV-disinfection robot comprises a mobile and autonomous circular platform (1), which is moved by wheels (2), each of which is independently controlled. The platform (1) has a rechargeable battery; a multifunctional sensor system including multisensors for orientation in space and for human movement; programmable processor modules equipped, if necessary, with self-learning algorithms building elements of artificial intelligence; a wireless communication unit via cloud technology for reporting the disinfection performed and the possibility of remote control. The platform (1) further comprises a panel UV-C emitter (3) located on its underside. This panel (3) is square in shape, maximally covering the area of the bottom of the platform (1). The linear velocity of the robot (1) is dimensioned so that the moving time over a distance as long as the length of the panel (3) is sufficient to disinfect an area of the floor as long as that of the UV-C emitter (3). A module (4) for providing audible information is also arranged on the platform (1).

Description

Siya Valcheva Lozanova Martin Lachezarov Ralchev August Yordanov Ivanov Chavdar Stanoev Rumenin

Sofia

ROBOT FOR UV-DISINFECTION

FIELD OF ENGINEERING

The invention relates to a UV-disinfection robot applicable to automated biological decontamination of infectious hospitals, including oncology clinics and multi-specialty medical facilities; reception rooms for patients; isolators specialized for the treatment of those infected with multi-resistant bacteria and superbugs, fungi, spores and viruses, including Ebola and Covid-19 infections; surgery rooms; kindergartens, schools, universities, research centers and scientific laboratories; barracks; hotel rooms and complexes; public and industrial buildings; airports; passenger aircraft lounges; offices; malls; homes for the elderly; social services and all other premises and areas requiring highly effective disinfection procedures combined with an ecological effect.

PRIOR ART

A UV-disinfection robot is known, comprising a self-contained mobile and autonomous platform of cylindrical shape, which is moved by wheels, each of which is independently controlled. There is a rechargeable battery in the platform; multifunctional sensor system, including multi-sensors for orientation in space and for movement of people; programmable processor modules equipped, if necessary, with self-learning algorithms, building elements of artificial intelligence; a block for wireless communication through cloud technology for a report of the performed disinfection as well as the possibility of remote control of the robot. The platform also contains an emitter of hard ultraviolet UV-C radiation, located on a stand at a certain height on the upper part of the cylindrical platform. The UV-C emitter includes a set of oblong lamps in the corresponding UV spectral range, which are arranged vertically and in a circle on the platform, [1 - 6].

A disadvantage of this UV-disinfection robot is the need during biological decontamination for patients and medical personnel to either leave the room, so as not to seriously damage their eye retina from the dangerous ultraviolet radiation, or to put on specialized protective masks to tightly cover the eyes beforehand and the face.

A disadvantage is also the unsatisfactory disinfection of the floor part of the premises, where the concentration of pathogens and especially the Ebola and Covid-19 viruses is the highest, since the UV emitter acts from a considerable distance (about 60 cm and more) on the floor.

Another disadvantage is the repeated exposure of the same part of the room surface by the robot with UV rays, due to the reduced radiation efficiency due to the large distance between the floor and the emitter.

TECHNICAL ESSENCE

The task of the invention is to create a robot for UV-disinfection, which has an increased efficiency of decontamination of the floor parts of the premises with a minimum number of exposures to radiation and to eliminate the need for patients and medical personnel to leave the premises or halls during UV -disinfection without the discomfort of face masks.

This task is solved with a UV-disinfection robot containing a self-contained mobile and autonomous circular platform that moves with wheels, each of which is independently controlled. There is a rechargeable battery in the platform; multifunctional sensor system, including multi-sensors for orientation in space and for movement of people; programmable processor modules equipped, if necessary, with self-learning algorithms, building elements of artificial intelligence; a block for wireless communication through cloud technology for a report of the performed disinfection as well as the possibility of remote control of the robot. The platform also contains a panel ultraviolet UV-C emitter located on its underside. This panel is square and covers the area of the bottom of the platform as much as possible. The linear travel speed of the platform is dimensioned so that the time to move the robot a distance equal to the length of the panel is sufficient to effectively disinfect a floor area the size of the square UV-C emitter. A module for providing sound information is also located on the platform.

An advantage of the invention is the highly efficient decontamination of the floor parts of the premises, since the design of the robot with the emitter ensure maximum intensity of hard UV-C radiation directly on the floor surface from a sufficiently close distance.

An advantage is also the elimination of the need for patients and medical staff to leave the premises during disinfection or to use uncomfortable protective masks, since people are not in the range of dangerous UV radiation.

Another advantage is the minimum number of exposures, practically reduced to one per corresponding part of the surface of the premises, due to the high efficiency of irradiating the floor from a minimum distance.

An advantage is also the timely warning with an audible signal of the approaching robot during its autonomous maneuvering between patients and staff, especially for people with specific needs (blind or difficult to move).

An advantage is also the reduced size of the disinfection robot due to the elimination of the need for a stand with oblong UV-C lamps.

DESCRIPTION OF THE ATTACHED FIGURES

The invention is explained in more detail with an exemplary embodiment given schematically in Figure 1, representing the underside of the platform together with the panel emitter, and Figure 2 shows the experimental dependence of the impact of hard UV-C radiation from the robot panel on the floor with a high concentration of bacteria and pathogens.

IMPLEMENTATION EXAMPLES

The UV-disinfection robot contains a self-contained mobile and autonomous circular platform 1, which is moved by wheels 2, each of which is independently controlled. There is a rechargeable battery in the platform; multifunctional sensor system, including multi-sensors for orientation in space and for movement of people; programmable processor modules equipped, if necessary, with self-learning algorithms, building elements of artificial intelligence; a block for wireless communication through cloud technology for a report of the performed disinfection as well as the possibility of remote control of the robot. The platform 1 further contains a panel ultraviolet UV-C emitter 3 located on the underside of the platform 1. This panel 3 is square and maximally covers the area of the bottom of the platform 1. The linear speed of movement of the platform 1 is dimensioned such that the travel time of the robot 1 at a distance equal to the length of the panel 3 is sufficient to disinfect an area of the floor equal to that of the UV-C emitter 3. A module 4 for providing sound information is also located on the platform 1.

The action of the robot for UV-disinfection, according to the invention, is as follows. For decades, ultraviolet rays have been used in medical practice to disinfect various contaminants of biological origin - bacilli, pathogens, viruses, etc. Although reliable gels and liquid disinfectants are already available, UV technology is the most effective means of disinfection. It functions without liquid chemicals, having a significant ecological effect. In general, UV rays destroy viruses and pathogens by high-energy electrons passing or diffusing through the protein coat into the core of their ribonucleic acid (RNA). This results in genetic damage to viral infection, particularly Ebola and Covid-19, [3,7]. Practice shows that particularly successful exposure (irradiation) takes place when the UV radiation is "hard", i.e. to be in the shortwave range of the spectrum. For this reason, the use of the UV-C range is preferred. The neutralization of microorganisms depends on the time of irradiation. UV-C rays are part of the UV-spectrum, along with its UV-A and UV-B components. Because UV-C radiation is completely absorbed by the Earth's atmosphere, microorganisms, including viruses, have no built-in natural resistance ¹ (resistance) in this short-wave spectral range. The other UV-A and UV-B rays penetrate the earth's surface and bacteria have developed a certain resistance to them.

This is the main reason for the effect of ultraviolet UV-C radiation as a disinfectant. For example, at a wavelength of 254 nm and four UV-C lamps on, each generating 5 joules of energy per second for the biological cleaning of a standard room takes about 10-15 min, [7].

The described principle of the effect of ultraviolet UV-C rays on viruses is also used in the new solution. For highly effective biological disinfection of floor surfaces, where the concentration of bacilli is maximum, emitter 3 with an innovative shape was used. It is made up of diode UV-C mini-emitters united in a panel unit 3. In our case, panel 3 is located on the underside of the circular platform 1, Figure 1. Thus, panel 3 is oriented to directly irradiate the floor from as close a distance as possible. This guarantees the high efficiency of UV-C floor disinfection. Another non-standard component of the solution used in the new UV-C disinfection robot is the square shape of the emitter 3. The size (side L) of the square is chosen to cover the maximum area of the bottom of the platform 1, Figure 1. The square shape creates equality in moving the robot to the left or to the right 1. In addition, high passability of the robot between possible obstacles in the room is ensured without stopping the disinfection process.

An essential part in the new solution is the linear speed v of moving the platform 1. If the movement is at a relatively high speed d, the UV-C effect is ineffective and repeated exposure of the same part of the floor surface is required. Conversely, if the movement of platform 1 is too slow, the decontamination takes too long. Therefore, the linear speed y of displacement should be dimensioned so that the time t for moving the robot 1 a distance equal to the length L of the panel 3 is sufficient to disinfect an area S of the floor equal to that of the emitter 3. Obviously, the expression for uniform and rectilinear motion L = v . t. In fact, the time t should be quite sufficient to move the square panel 3 from one end to the other at a speed v to completely eradicate the pathogens in an area S = L . L = L . Since the emitter 3 is square, the direction of movement of the platform 1 - left or right - does not matter. Figure 2 shows the experimentally obtained dependence of the action of the UV-C panel 3 on a floor surface naturally infected with bacilli, using a generally accepted biological method for the purpose. The graph in Figure 2 contains the results of colony forming units (CFU) as a function of the time t of irradiation, CFU(i). The Zee panel used in the prototype of the UV-robot has size L ~ 10 cm and area S ~ 100 cm ² . At the fixed speed v = const of moving the platform 1, the complete destruction of pathogens with UV-C rays takes place in time t ~ 3 s. The time t and the speed v are also determined by the intensity of the panel emitter 3. As the intensity of UV-C radiation increases, the exposure time t of the square panel 3 decreases, and vice versa.

The module 4, located appropriately on the robot 1, provides sound information from the approach of the system 1 to people, for example with specific needs, during disinfection. Also, through module 4, various information can be given to patients or serve to entertain children. There is also no need to leave the disinfecting room or to use protective equipment, since the design of the robot 1 is such that there is no dangerous UV-C radiation in the area where people are present. The omission of the stand on which the UV lamps are placed in the known solution leads to a reduction in the dimensions of the new robot. If long-term disinfection of rooms is necessary, the robotic system 1 can also be powered by the mains.

The unexpected positive effect of the new technical solution is in the original design of the emitter 3 and its non-standard location on the underside of the platform 1, which ensures the impact of UV-C rays directly from a short distance on the biologically contaminated floor surfaces. The optimal speed v of moving the robot guarantees the destruction of bacteria practically with only one exposure without repeating the procedure. The solution ensures that patients and doctors are not exposed to dangerous ultraviolet radiation.

The square shape of the UV-C panel 3 can be replaced with a round one if necessary. In all cases, however, the requirement is that the area of the underside of the platform 1 is maximally covered by the radiating panel 3, which increases the efficiency of the system.

The process of disinfecting a hospital environment with the help of the new robot minimizes the risk of infecting front-line medical personnel with the two most dangerous virus carriers of a pandemic nature, Covid-19 and Ebola. The new robot also greatly reduces surgical and nosocomial infections. To a certain extent, through the action of emitter 3, the air in the offices can also be decontaminated. The system of Figure 1 is of universal applicability to all types of premises and buildings, especially passenger aircraft cabins due to their small dimensions, which transport in the conditions of Covid-19 is a serious challenge in tourism. The action of the new robot guarantees an ecological effect compared to using gels or sprays. They are extremely unfavorable for people with lung problems - for example asthma, and not least pets. The new solution is completely safe for use in kindergartens and schools.

APPENDIX: two figures

LITERATURE

[1] R. Todd, Ultraviolet disinfection device and method, World Patent, WO2015116876/06.08.2015.

[2] N. Harmon, R. Douglas, Mobile disinfectant device and method, US Patent, US822688B2/24.07.2012.

[3] Z. Liang, Z. Jiaxin, Disinfection robot, China Patent Appl., CN110089980A/06.08.2019.

[4] B. Hoaqiang, C. Qike, Z. Pengbo, Intelligent comprehensive sterilization robot, China Patent Appl., CN106362173A/28.09.2006.

[5] B.H. Moore, M.J. Botos, Self-propelled sterilization robot and method, US Patent Appl., US20080056933A1/29.08.2006.

[6] Z. Heshend, Robot for ultraviolet sterilization, China Patent Appl., CN105963730A/09.05.2006.

[7] F. Vatansever, W. Melo, A. Veccio, D. Sadasivam, M. Gupta et al., Antimicrobial strategies centered around reactive oxygen-species-bactericidal antibiotics, photodynamic therapy, and beyond, FEMS Microbiol. Rev., 37(6) (2013) pp. 955-989.

Claims (1)

A UV-disinfection robot containing a self-contained mobile and autonomous circular platform that moves with wheels, each of which is independently controlled, the platform has a rechargeable battery; multifunctional sensor system, including multi-sensors for orientation in space and for movement of people; programmable processor modules equipped, if necessary, with self-learning algorithms, building elements of artificial intelligence; block for wireless communication through cloud technology for reporting disinfection carried out as well as the possibility of remote control of the robot, the platform also contains an ultraviolet UV-C emitter, CHARACTERIZED by the fact that the emitter (3) is a panel, located on the underside of the platform (1) and is square, maximally covering the area of the bottom of the platform (1), the linear speed of the robot (1) is dimensioned so that the time for its movement a distance equal to the length of the panel (3) is sufficient to disinfect the floor area as much as that of the UV-C emitter (3), the configuration (1) also has a module (4) for providing sound information.