The invention relates to a system and method for observation of newborn babies in a maternity hospital over the internet. The invention belongs to the domain of video signal transmission via Internet combined with payment terminals. The system according to the invention enables live video transmission from the maternity hospital 24 hours continuously. The system includes IP cameras (1), which are mounted in the carriers in a maternity hospital above babies' beds and via router (2) and Internet links related to the media server (3) and web server (4). Users access the system via a known Web address.

The present invention, generally speaking, belong to the field of packaging intended for the storage, handling and delivery of goods from producers to users or consumers, and observed closer, to the area of transport packaging for stacking up packaging of smaller units intended for one-time use, and specifically refers to light ecological packaging for plastic cups, primarily intended for buttermilk, Greek yoghurt, soft cheese, pudding and the like. Cardboard crate for the plastic cups is made from recycled cardboard in a known way of pressing and has a body (1) in form of a hollow pyramid with rounded vertices (2) in which is symmetrically displaced twenty-integrally designed projections (3) in form of octagonal pyramid positioned to form the cup beds (5) with lateral sides inclined under an angle of 75° in which are freely and easily inserted standard plastic 0.2 Itr. cups (10) filled with milk products.

The invention relates to a building structure comprising composite floor slabs and pre-cast wall panels. The floor slabs comprise a styrofoam block (1) having longitudinal (2) and transverse channels (3) cut into an upper surface, the channels are provided with reinforcement and spacers therefor and are filled to first depth with concrete. Such a pre-cast slab may be transported to a building site and the floor structure finished by applying a reinforcing mesh and additional concrete. The pre-cast wall panels comprising a plurality of insulating formwork building blocks made of light concrete provided with cavities and channels, some of which are cast with vertical and horizontal reinforced concrete.

iStreetLight (hereinafter ISLS) street lighting system according to the invention represents a new concept in urban infrastructure building which in addition to lighting has active interaction with the environment by collecting data via sensor array related to atmospheric conditions and traffic conditions. At the same time platform is using solar energy and / or kinetic energy of moving vehicles and transmit radio waves related to utility, navigation and value added services. ISL is a device in the form of standard street lamp with the pole, which is composed of a central microprocessor component iCore (1E), LED bulb (1 K), communication module (1C), sensor array module (1B), module for energy collection iHarvest (1G), battery (1 H) and module for utility and value added services broadcasting to the end users (1D). All components are electrically connected and packaged in one or more water resistant box. Each ISL in network communicates with central system iStreetHost (hereafter ISH) (2D) via wireless network (2B) and the Internet (2C) sending all gathered data and ISL status information. Central ISH system (2D) is performing collection, storage and processing of data received from the ISL network, estimates traffic and microclimate conditions in ISL network area. ISH (2D) estimation results and the data required for the additional service sends back to the interested users via ISL network by using ISL transmission module (1D) and provides them available to the internet users (2C). ISL is collecting energy from the environment by iHarvest module (1G), which is receiving solar panel (1A) output and / or energy output from devices based on electroactive polymers EAP (1L) collecting kinetic energy of moving vehicles. iHarvest module (1G) and is connected to the power distribution network via connection (1F). ISL uses energy from the distribution system only when the energy level in the battery (1H) is below the defined limit of sufficient power for ISL. Figure 1 - Elements iStreetLight lamps Figure 2 - Communication between iStreetLight devices (2A) with iStreetHost (2D) central system and with environment (2E) Figure 3 - Block schematic of iSensor module

Shelf for bottles made of big number of elements (10) interconnected with elements (11) in horizontal line. Bigger number of horizontal lines is connected in the same way in vertical direction, forming honey comb shelf structure between elements (10, 11) the holes (14) are formed for bottle storage. Elements (10 and 11) are interconnected by caps (12) inserted in holes (13) made in elements (10, 11). Element (10) made out from one piece of octangular cross section, with the convex sides (101), and concave sides (102) Alongside elements (10) the holes (13) are made on sides (101). Element (11) made out with approximately rectangular cross section, with slightly concave sides (111, 112). The holes (13) are made on sides (112). The caps (12) "are inserted in holes (13) on elements (10 and 11) connecting it in one piece.

By winding of successive packages P1, P2, P3…Pi…Pn Figure 3 with shifted beginnings compared to the previous margins m2, m3…mi…mn Figure 3 on the rectangular rounded base AxB/R Figure 1 out of different width tapes w1, w2, w3…wi…wn Figure 3 in package heights h1, h2, h3…hi…hn Figure 3 rectangular hank K Figure 1 is made with half notched circle cross section of diameter d Figure 3 with lateral edges of packages P1, P2, P3…Pi…Pn Figure 3 made so that first few packages are constrained by the circumcircle and the inner edges of the other packages are lying in the plane inclined at 30 degrees to the perpendicular of winding axis and the opposite outer edges of the packages are touching the circumcircle of base AxB/R Figure 1 of diameter d Figure 3, and by connecting three identical hanks K Figure 1 by leaning planes S Figure 1 delta magnetic core Figure 2 is made.

The bottle with a capsule contains a cavity into which a capsule is inserted (10). The capsule is inserted into the cavity (2) on the body of the bottle up to the point the adhering surfaces are settled and fixed by insertion of a convexity (3,15) on the bottle into the cavity (12,14) on the capsule by which the stability of the unit is achieved. The invention refers to the designing solution of the body of the bottle and the capsule in order to fix the capsule with the bottle in a tight but separable way, and at the same time to provide the stability of the unit. The invention belongs to the area of production of PET packaging.

The invention relates to a blood bag valve breaker, in which the output shaft of the electromotor (1) is coupled with the excenter (2) inside the housing (K). The connecting lever (3) of the excenter-lever mechanism is rotationally connected on one end to the excenter (2), and on the other end to the push rod (4). On the push rod (4) the fork (5) is attached, beneath which a fixed fork (6) is placed on the housing (K). Beneath the fork (6) the spikes (7) with the slipped openings (82) constructed on the reinforcement (81) of the bag (8) are placed. Between the forks (5, 6) the valve (83) of the bag (8) is placed, in such a manner that the rotation axis of the fork (5) is positioned, approximately in the axis of the fork (6), that is in the centre of the valve (83). On the outer sides of their arms the movable fork (5) and the fixed fork (6) have built-in screws (51, 61), respectively, which through springs (not shown in the drawings), press the balls (52, 62), respectively, in between of which the valve (83) is positioned.

The distillation-power unit (4) of a distillery/refinery (1) consists of a radial flow steam driven ducted impeller (71) which is driven by steam released from bubbles coming on the surface of liquid for distillation contained in a cyclone conical container (13, 70) and multi-stage axial flow bubble driven ducted impeller (72) which is driven by bubbles of saturated steam ascending from the heated bottom of container (13, 70). The steam and bubble driven impeller (71, 72) are fixed to an outer and inner vertical shaft (75, 76) of induction generator/motor (7) respectively. Exhaust steam is condensed inside the top cap/fan casing (10) of steam driven impeller (72). Vapor from the cap/fan casing (10) is delivered to the condensation unit (5) where it is condensed into fuel for supplying a burner which burns fuel and heats the bottom of container (70). Non-condensed gases returns into the distillation-power unit (4).

The device and procedure for remote diagnostic and management of automated technical devices (1) of standard construction, according to the invention, is consisted of a device including a series of video cameras (2) which are connected in parallel and a series of transducers (3) for signal conditioning also connected in parallel, where the video cameras (2) and the transducers (3) are connected to the central processing unit (CPU1) to which the memory (M) is also connected and where the central processing unit (CPU1) is by a communication channel (KK) connected to the central processing unit (CPU2) with the memory (M), where the central processing unit (CPU2), through the line (4) of the video recording and the line (5) of the textual file is connected to the assembly (6) for processing video and text data to which a monitor with a screen (D) and an input unit (7) are connected, and wherein each of the electrical and/or mechanical working or mobile assemblies (11, 12, 13, etc. 1n) of the device (1) is recorded by video cameras (2) from which the video recordings and the working parameters of the textual files are through transducers (3) which condition the signal by using A/D and/or D/A converters to transform the working signals into signals understandable to the central processing unit (CPU1), where the (CPU1) storages the video recording into the memory (M), and where (CPU1) storages also the textual files with the data on the working parameters of the observed assemblies of the device (1) and where the content of the memory (M) is through a communication channel (KK) sent to the central processing unit (CPU2) at a remote location where monitoring and control of the observed device (1) is being conducted, where the central processing unit (CPU2) storages these data into its memory (M) wherefrom the video recordings, through a line (4), and the textual file data, through a line (5), are sent for processing into the assembly (6) and displayed on the screen (D) of the monitor, where the video image of the observed assembly with the data on the actual state of the parameters of that assembly (real state) are compared to the data which represent proper functioning of the observed device (1), where in case that these data do not match we have diagnosed a potential malfunction of the device, and where the assembly (6) is connected to an input unit (7) for sending commands to the assembly which is not working properly by which it will perform the proper operation.