RU180003U1 - Device for transmitting and metering liquids - Google Patents

Abstract

This utility model relates to techniques for filling and metering liquids and can be used to transfer various types of liquids in production, in automotive services. A device for transmitting and metering a liquid comprises a pump, which transfers from a source container of a liquid supplied to a pump inlet to a target tank from a pump outlet; a suction hose immersed in the source tank for the purpose of pumping fluid from the source tank for transfer to the target tank; pump outlet for pump fluid transfer to the target tank; fluid flow meter for measuring the amount of fluid transmitted by the pump; tilt and shock sensor for recording the fact of tilting the device and the fact of an impact on the device; tamper sensor to establish the fact of finding the device at the original capacity; liquid level sensor for measuring the amount of liquid in the original container; fan; Power Supply; rechargeable battery; an information display module for displaying a device state; speaker for playing sounds; a fluid supply enable button to start pump fluid supply; fluid shutdown button; button to increase fluid flow; fluid reduction button; button on and off the device; pump and fan relay supplying voltage to the fan and pump; a charge and power regulator relay supplying voltage from the battery to the device; a communication module that transfers data from the device to the server; a computing module that monitors, controls and operates the device, and also receives signals from sensors, a liquid flow meter, and also receives signals from the pump and fan relays and the relay of the charging and power regulator and sends signals to the mentioned relays, and also receiving signals from the communication module and transmitting signals and data to the communication module for sending to the server; at the same time, a liquid flow meter, tilt and shock sensor, tamper sensor, liquid level sensor, information display module, speaker, fluid supply enable button, fluid supply increase button, device on and off button, pump and fan relay, charge and power control relay , the communication module is configured to connect to a computing module. The technical result is an increase in accuracy. 15 s.p. f-ly, 5 ill.

Description

This utility model relates to techniques for filling and metering liquids transferred by a pump from one tank to another, and can be used to transfer various types of fluids in production, automotive services, and the utility model can also be used indoors and (or ) on tanks, where there is a lack of space for the installation of devices for the transfer and metering of liquids, which carry out at least the transfer and metering of fluid transferred from one tank to another.

The prior art device for measuring mass flow with sensors, angular velocity sensors with cylindrical magnets and windings, an electronic unit, and the device is connected to the pipeline (Patent RU 2153652, publ. 27.07.2000). The disadvantage of this method is the lack of compact elements that allow the manufacture of a compact device for metering fluid transferred through a pump from one tank to another. Also, this patent does not describe the use of a pump, tilt sensors, shock, measuring the liquid level in the source tank, from which the fluid is transferred to the target tank.

Also known is a method of accounting for fuel consumption and a device for its implementation (Patent RU 2241210, publ. November 27, 2004), which describes a method and device for measuring the mass of liquids, in particular fuel sold to a consumer through a fuel dispenser (fuel dispenser) of a gas station . A method of accounting for fuel consumption is proposed, in which the total released volume of fuel from the tank and the sum of the instantaneous doses of the volume of fuel delivered to the consumer are brought to one standard temperature. After comparing these volumes, the consumer releases the amount of fuel corresponding to the total amount of fuel dispensed from the tank, while the consumer pays for the ordered amount of fuel in accordance with its mass, the density of which corresponds to the density of the fuel at standard temperature. A device for accounting fuel consumption is proposed, including a sensor for initial fuel temperature and a density meter installed in a fuel storage tank. The device comprises a throughput device with a pump installed on its discharge pipe, a fuel cut-off device, a current fuel consumption temperature transducer, a pulse volumetric meter, and a power unit electrically connected to the pump and the fuel cutter. The device has an electronic calculator with a microcontroller and its memory unit, a pulse shaper, a dose corrector associated with the temperature converter of the current fuel consumption and a pulsed volume counter associated with the microcontroller, an indication panel. In addition, the device comprises a fuel consumption volume adjuster, a comparison unit, a control device electrically connected to the power unit, which is installed in the throughput device, a pulse adder and a conditionally constant density adjuster. The technical result from the use of inventions is to create conditions for accurate metering of fuel consumption and its dispensing by creating a device that provides metering of the consumption of a given amount of fuel according to its mass, calculated independently of the changing temperature and density of the fuel during its dispensing. The disadvantage of this solution is the need to bring the total volume of fuel delivered from the tank and the sum of the instantaneous doses of the volume of fuel delivered to the consumer to one standard temperature, as well as the need to compare the volumes mentioned, the need to use a sensor for the initial fuel temperature and density meter, a temperature converter for current fuel consumption, and a dose corrector. Also a drawback of such a device is its dimensions, which makes it difficult to move such a device from (or c) one source capacity to (or) another capacity. Another disadvantage is the need to use fuel dispensers.

The technical result achieved when using the utility model is to eliminate the disadvantages of devices known from the prior art, namely, to reduce the size of the component parts of the device while increasing the compactness of the device as a whole, as well as the ability to measure the liquid level in the original tank by using a level sensor fluid, as well as a tilt and (or) shock sensor, which allows you to determine the impact on the described device with the implementation of more efficient use I device for fluid transfer from one container to another. The mentioned effects lead to a decrease in the accuracy of measuring the liquid level in the original tank.

The specified technical result is achieved due to the fact that the device for transmitting and metering liquids comprises a pump configured to transfer from the original capacity of the liquid supplied to the pump inlet to the target capacity from the pump outlet; a suction hose immersed in the source container and configured to pump the fluid from the source tank to transfer to the target tank; the pump outlet, configured to transfer fluid to the target tank; a liquid flow meter, configured to measure the amount of liquid transmitted by the pump from the source tank to the target tank; a tilt and shock sensor configured to record the fact of tilting the device and the fact of an impact on the device; tamper sensor, configured to monitor the fact that the device is on the original capacity; a liquid level sensor configured to measure the amount of liquid in the original container; a fan configured to cool the device; a power supply unit configured to supply voltage to the device; a battery, configured to supply voltage to the device in the absence of voltage from the power supply; an information display module configured to display a state of a device; a speaker configured to play sounds when interacting with the device and changing the state of the device; a fluid supply enable button configured to start pumping fluid from a source tank to a target tank; a button to turn off the fluid supply to end the transfer of fluid by the pump from the source tank to the target tank; a button for increasing the liquid supply to increase the amount of liquid transferred by the pump from the source tank to the target tank; a button for reducing the fluid supply to reduce the amount of fluid transferred by the pump from the source tank to the target tank; button on and off the device; a pump and fan relay configured to supply voltage to the fan and pump; a charge and power regulator relay configured to supply voltage from the battery to the device in the absence of voltage from the power supply; a communication module configured to transmit data from the device to the server; a computing module configured to monitor, control and operate the device, as well as receive signals from the tilt and shock sensor, tamper sensor, liquid level sensor, liquid flow meter, and also receive signals from the pump relay and fan (cooling) and the relay of the charging and power regulator and send signals to the said relays, as well as receive signals from the communication module and transmit signals and data to the said module links for further delivery to the server; at the same time, a liquid flow meter, tilt and shock sensor, tamper sensor, liquid level sensor, information display module, speaker, fluid supply enable button, fluid supply increase button, device on and off button, pump and fan relay, charge and power control relay , the communication module is configured to connect to a computing module.

In the particular case of implementation, the pump device for transmitting and metering liquid is an electric pump.

In the particular case of implementation, the pump of the device for transmitting and recording liquid is an oil pump.

In the particular case of implementation, the pump device for transmitting and metering liquid is an electromechanical pump.

In the particular case of implementation, a liquid flow meter of a device for transmitting and metering liquid is installed between the inlet of the pump and the intake hose.

In the particular case of implementation, the liquid flow meter of the device for transmitting and recording liquid is part of the pump.

In the particular case of implementation, a liquid flow meter of a device for transmitting and metering liquid is installed between the pump outlet and the pump outlet.

In the particular case of implementation, the communication module of the device for transmitting and recording liquid is a GSM / GPS module.

In the particular case of implementation, the communication module of the device for transmitting and recording liquid includes a SIM card.

In the particular case of implementation, the opening sensor of the device for transmitting and recording liquid is a reed switch.

In the particular case of implementation, the liquid level sensor of the device for transmitting and recording liquid is an ultrasonic range finder.

In the particular case of implementation, the speaker of the device for transmitting and recording liquid is a piezoelectric speaker.

In the particular case of implementation, the information display module of the device for transmitting and recording liquid is a liquid crystal monitor.

In the particular case of implementation, the on / off button of the device for transmitting and recording liquid is a toggle switch.

In the particular case of implementation, the communication module of the device for transmitting and recording liquid is configured to determine the geographical coordinates of the location of the device for transmitting and recording liquid.

In the particular case of implementation, a refueling gun is attached to the outlet of the pump of the device for transmitting and recording liquid.

The essence of the utility model is illustrated by the images:

FIG. 1 illustrates a top view of a device;

FIG. 2 illustrates a side sectional view of an apparatus;

FIG. 3 illustrates the general diagram of the elements of the described device, the relationships and interactions between them.

FIG. 4 illustrates one embodiment of a device.

FIG. 5 illustrates one embodiment of the device from above.

The device (100) shown in FIG. 1-FIG. 5, contains a housing (110, FIG. 1), on which are located the components of the described device (100), including:

- a pump (115, FIG. 1), in particular, an electric pump, which may be an oil pump, a liquid pump, an electromechanical pump, a centrifugal pump, pump pump, etc. The pump (115, FIG. 1) carries out (configured to implement) the transfer (supply, pumping, etc.) of liquid (220, FIG. 2) from the source tank (210, FIG. 2) to the target tank (105, FIG. 1). It is worth noting that the initial capacity (210, FIG. 2) can be any capacity, in particular, a barrel, a tank, etc. The initial container (210, FIG. 2) may have a non-removable top cover or a removable upper cover, and also have necks (in particular, openings 265 and 275, FIG. 2), the axes of which are arranged vertically, etc., and the initial container can be sunset, welded, etc. and can be made of any known material, for example, metal, plastic, etc. In turn, the target container 105 may be a canister, barrel, etc., made of any known material and have at least one hole for pouring liquid into such a target container. A suction hose (235, FIG. 2) is connected to the pump (115, FIG. 1) through a hole (270, FIG. 2) in a housing (110, FIG. 1) through a hole (275, FIG. 2) in the original tank (210, FIG. 2) and immersed in a liquid (220, FIG. 2) of the original tank (210, FIG. 2). It is worth noting that the holes (270 and 275, Fig. 2) may have different diameters, in particular matching the diameter of the intake hose (235, FIG. 2), or may be of the diameter of said intake hose. Also, the openings (270 and 275, Fig. 2) may have different cross-sectional shapes, in particular, matching or not matching the cross-sectional shape of said intake hose. It is also worth noting that the intake hose (235, FIG. 2) can have different lengths (as well as the outer and inner diameters), in particular, necessary to supply all the fluid (220, FIG. 2) or at least part of such liquid from the source tank (210, FIG. 2) to the target tank (105, FIG. 1) by means of a pump (115, FIG. 1). It is also worth noting that, in case of insufficient length of the intake hose (235, FIG. 2) for transferring all or part of the liquid (220, FIG. 2) from the source tank (210, FIG. 2) to the target tank (105, FIG. 1), the intake hose (235, FIG. 2) can be extended, in particular by attaching (in one of the known ways) to the intake hose (235, FIG. 2) an extension of said intake hose, the extension may be a hose, pipe, profile etc. different lengths and sections (internal and external), and can also be made of various materials (metal, plastic, rubber, composite materials, etc., as well as their combinations) with different stiffness and flexibility. It is worth noting that instead of the intake hose, a pump intake (inlet) nozzle can be used, to which the mentioned intake hose can be connected (235, FIG. 2). It is worth noting that the intake hose (235, FIG. 2), in a particular case, made (made), for example, in the form of a pipe, tube, hose, etc.) is used to carry out the fluid intake (220, FIG. 2) from the source tank (210, FIG. 2) for transmission by a pump to the target tank (105, FIG. 1). Also, the pump (115, FIG. 1) includes an outlet pipe (120, FIG. 1), also called a bulk pipe. The outlet pipe (120, FIG. 1) is used to deliver (transfer) liquid (220, FIG. 2) from the pump outlet (115, FIG. 1) to the target tank (105, FIG. 1), and the outlet pipe (120, FIG. 1) can be fixed to the outlet (in particular, the outlet pipe or pipe) of the pump (115, FIG. 1) or be an integral part thereof. It is worth noting that instead of the outlet pipe (120, FIG. 1), also known as the inlet pipe, an outlet hose (inlet hose) can be used. It is also worth noting that, in case of insufficient length of the outlet (bulk) nozzle (120, FIG. 1) of the pump (120, FIG. 1), such an outlet nozzle of the pump (120, FIG. 1) can be extended, in particular by connecting (in one of the known ways) to the outlet pipe of the pump (120, FIG. 1) an extension for said outlet (bulk) pipe (120, FIG. 1), the extension may be a hose, pipe, etc. various lengths and sections (internal and external), and can also be made of various materials. It is also worth noting that to the pump outlet (120, FIG. 1) or the outlet (bulk) pipe (120, FIG. 1) of the pump (120, FIG. 1), a filling gun (also called a filling valve, dispensing valve and etc.), and between the pump outlet (120, FIG. 1) or the outlet (bulk) pipe (120, FIG. 1) of the pump (120, FIG. 1) a hose can be used, in particular, with the aim of filling the target capacity 105 located at a (significant) distance from the device 100.

- a liquid flow meter (125, FIG. 1) connected to the pump outlet (115, FIG. 1) and recording (in particular, determining) the quantity (in particular, the mass and / or volume, depending on the type of sensor used) liquid (220, FIG. 2), pumped (spilled, spilled, poured, transferred, pumped, etc.) by the pump (115, FIG. 1) from the source tank (210, FIG. 2) to the target tank (105, FIG. 1). It is worth noting that in a particular case, a liquid flow meter (125, FIG. 1) can be installed between the pump outlet (115, FIG. 1) and the outlet (bulk) pipe (120, FIG. 1) of the pump. Also, it is worth noting that in a particular case, the liquid flow meter (125, FIG. 1) can be mounted on the housing of the described device (100). In another embodiment, a liquid flow meter (125, FIG. 1) can be installed in the outlet (bulk) pipe (120, FIG. 1) of the pump (120, FIG. 1), i.e. be part of the outlet (bulk) pipe (120, FIG. 1). Also, it is worth noting that in the particular case, a liquid flow meter (125, FIG. 1) can be installed between the outlet (bulk) pipe (120, FIG. 1) and an extension for the said output (bulk) pipe (120, FIG. 1) ) It is worth noting that in the particular case, a liquid flow meter (125, FIG. 1) can be installed between the pump inlet and the intake hose (235, FIG. 2). In a particular case, the liquid flow meter (125, FIG. 1) is part of the pump (120, FIG. 1), in particular a component of said pump. In a particular case, the liquid flow meter (125, FIG. 1) is a flow meter (in particular a flow meter), which allows you to change the volumetric or mass flow rate of the liquid. Also, the fluid flow meter (125, FIG. 1) may include an integrating device (meter) with the ability to simultaneously measure the amount of fluid (220, FIG. 2) pumped by the pump (115, FIG. 1) from the original tank (210, FIG. . 2) in the target capacity (105, FIG. 1). Also, the liquid flow meter (125, FIG. 1) can be a mechanical meter, a wing meter (multi-jet or single-string), a turbine meter, a flow meter, a turbine meter with a mechanical meter, a turbine meter with an induction signal pickup, an electromagnetic flowmeter-counter, vortex flowmeter-counter (including with an inductive signal converter, with an electromagnetic signal converter or with an ultrasonic signal converter), ultrasound a liquid flow meter, a liquid differential pressure meter, a constant differential pressure meter (rotameter), etc. It is worth noting that the fluid flow meter (125, FIG. 1) may include a reed switch, a Hall sensor, use of an optocoupler (optical pair), etc. In the particular case, according to the conversion from the fluid flow sensor 125, the error is not significant, so one pulse (pulse output) of the fluid flow sensor 125 is equal to one liter. It should be noted that in the particular case, the fluid flow sensor 125 can be supplemented with an additional reed switch. The pulse output is based on the action of the magnetic field of a permanent magnet on the reed switch, in which there is an alternating closure and opening of the contacts of the reed switch. Reed switch generates a passive output signal ("dry contact").

- a computing module (140, FIG. 1), which in a particular case is a (universal) computing device (140, FIG. 1), which may also be a multifunctional computing device, a microcontroller, or contain at least one microcontroller, special case, programmable microcontroller. Such a computing module (140, FIG. 1) can be Intel Galileo, Raspberry Pi, Arduino, in particular, AT-Mega328, as well as other analogs (in particular, using Arduino, etc.). Also, the computing module (140, FIG. 1) can be any known programmable microcontrollers, microcomputers, computers, computers, personal computers, personal computers, mobile computing devices (such as smartphones, tablets, mobile phones, etc.) and other computing devices . It is worth noting that the computing module (140, FIG. 1) monitors, controls and operates the described device (100) and at least one of its constituent elements (parts), in particular, receives signals from buttons 291, 292, 295, 296 (FIG. 2) and others, and also receives signals (in particular, data) from sensors 195, 125, 165, 130, etc., and also receives signals (in particular, data) from a relay 145 and 180 and sends signals (including control signals) to the mentioned relays, as well as receive signals (in particular, data) from the communication module 150 and sends signals (including control signals) and data to the said communication module, in particular, for further sending in the form of at least one message to the server.

- a communication module (150, FIG. 1), in a particular case being a GSM / GPS module, which transmits data to the server, in particular, in the format of at least one message (hereinafter the message to the server) sent to the server ( via html (web), SMS messages (SMS messages), etc.), and such data may contain data on the current mode (which are described in more detail below) of the device 100, the status of the device 100 (in particular, the feed ( spill, etc.) liquid, etc.), battery charge level 185, level sensor values (readings) liquid 165, values (indications) of the liquid flow sensor 165, (geographical) coordinates of the location of the device 100 (GPS coordinates), identifier for turning on or off (in particular, pressing) at least one of the described buttons (or device 100) moreover, the identifier, in particular, is a bit value (0 or 1) that identifies the correspondence status of the pressed button and its function (for example, in the absence of fluid supply, the identifier is “0”, when the fluid supply is turned on, the identifier changes tsya from "0" to "1", and false triggering is fixed when disconnected, respectively, to "0", then performed a computation module status check means 140 when such data do not match), etc. The communication module (150, FIG. 1) may be part of a computing module (140, FIG. 1) or may be connected (connected, connected, etc.) to the computing module (140, FIG. 1) by any known type ( type, method, etc.) of connection, for example, via a wired connection (communication) top or wireless connection type. So, between the communication module (150, FIG. 1) and the computing module (140, FIG. 1) communication (connection) can be established by using known wired and / or wireless means, devices, etc. communications and connections. The communication module (150, FIG. 1) can use (or include, allow to install / integrate, etc.) a SIM card (from the English Subscriber Identification Module - Subscriber Identity Module), which is the subscriber’s identification module used in mobile communication for transmitting said data to a server. In the particular case, the communication module (150, FIG. 1) is a GSM / GPS-compatible card (extension) for the computing module (140, FIG. 1), for example, the SYM800L transceiver, any analogue that allows receiving and data transmission via 2G, 3G, LTE, etc. technologies

- a relay of the pump and fan (cooling) (145, FIG. 1), which is connected to the computing module (140, FIG. 1), which controls the said relay of the pump and fan (145, FIG. 1) via a control cable, moreover, the relay the pump and fan (145, FIG. 1) allows you to supply voltage to the fan 155 and pump 115, and the supply voltage of the pump 115 and fan 145 may be 220 Volts (or any other voltage for the operation of the aforementioned pump and fan, depending on the type of fan or pump, in particular, from Parts Required voltage for their operation), as described hereinafter. It is also worth noting that the pump and fan relay (145, FIG. 1) can be part of a computing module (140, FIG. 1) or can be connected (connected) to a computing module (140, FIG. 1) by any known type ( type, method, etc.) of connection (connection), in particular, wired type of connection. It is also worth noting that the relay of the pump and fan (145, FIG. 1) may be a solid state or electromechanical relay.

- a relay for charging and power control (180, FIG. 1), which supplies voltage from the battery 185 to the computing module (140, FIG. 1) and the described sensors 195, 125, 165, 130, etc. in the absence of power to the device 100 (voltage in the electric network 220 Volts and, in particular, power from the power supply 135). It is also worth noting that the relay of the charging and power regulator (180, FIG. 1) can be part of a computing module (140, FIG. 1) or can be connected (connected) to a computing module (140, FIG. 1) by any known type (type, method, etc.) connection (s), in particular, wired type of connection. It is also worth noting that the relay of the charge and power regulator (180, FIG. 1) can be a solid-state or electromechanical relay.

- a fan (cooling) (155, FIG. 1), in particular, an electric fan for cooling the device 100, in the particular case of elements (contents of the housing (110, FIG. 1), in particular, a pump (115, FIG. 1) , computing module (140, FIG. 1) and others) of the described device (100).

- a power supply unit (135, FIG. 1) that converts the supplied voltage (in particular, 220 Volts) into the voltage necessary for the functioning of at least one described element (in particular, part) of the described device 100 or the entire device 100 and supplying the necessary voltage for powering (in particular, functioning) the relay of the pump and fan (145, FIG. 1) and the relay of the charge and power regulator (180, FIG. 1), and, in a particular case, the first circuit of the power supply unit (135, FIG. . 1) supply voltage (220 volts, or any other required voltage) to the relay of the pump (115, FIG. 1) and fan (145, FIG. 1), and the second circuit supplies voltage (for example, 5 Volts, 12 Volts, 24 Volts, etc.) to the relay charge and power regulator (180, FIG. 1), the described sensors, etc. It should be noted that the aforementioned first power supply circuit (135, FIG. 1) can supply voltage not only 220 Volts, but also any other voltage sufficient for the pump and fan relays to function (145, FIG. 1), as well as pump 115 and fan (cooling) 155. It is also worth noting that the aforementioned second circuit of the power supply unit (135, FIG. 1) supplies any other (different from the above) voltage sufficient for the functioning of the above sensors, relays, etc.

- a rechargeable battery (185, FIG. 1) providing power (supplying the necessary voltage) to the computing module (140, FIG. 1), the described relays and the described sensors 195, 125, 165, 130, etc. in the absence of power to the device 100 (for example, in the absence of voltage in the 220 V electric network, including power from the power supply unit 135, for example, in the event of a malfunction of the power supply 135, lack of voltage in the (electric) 220 Volt network supplying the device 100 etc.).

- tamper sensor (130, FIG. 1), used to establish the fact of "removal" ("separation", etc., that is, when the device 100 rises above the target capacity 210 or is removed from the target capacity 210) of the device 100 s target capacity 210, i.e. in particular, it controls the fact that the device 100 is on the original container 210. In the particular case, the tamper sensor (130, FIG. 1) is mounted outside the device 100 and fixes the device 100 from the target tank 210. In the particular case, the tamper sensor (130, FIG. 1) can be installed inside the device 100. It is also worth noting that at least one part of the tamper sensor (130, FIG. 1) can be installed inside the device 100, and the other part of such a sensor can be moved outside the device 100 in particular on its lower part (under the device 100, in particular under the bottom surface, in the particular case being the bottom cover of the device 100). So, the tamper sensor (130, FIG. 1) can be, for example, a reed switch, a button, a contact pair, etc. It is worth noting that, for example, in the case of using a reed switch, one part of the reed switch can be mounted on the device 100, and the other part (in particular, the counterpart) on the target capacity 210.

- information display module (175, FIG. 1), which in a particular case is a monitor of the state of the described device (100) and its components (elements). So, for example, such an information display module (175, FIG. 1) can be, for example, a liquid crystal monitor, a character matrix display, or any other device for outputting graphic and text information known from the prior art.

- liquid level sensor (165, FIG. 1), which allows the measurement of the amount (in particular level) of the liquid (220, FIG. 2) in the original tank (210, FIG. 2). So, for example, the liquid level sensor (165, FIG. 1) may be an ultrasonic sensor. In the particular case, the liquid level sensor (165, FIG. 1) can be implemented by an ultrasonic range finder (for example, jsn-5r04t, which is a sensor with a controller), as well as any known immersion, condenser and other types of liquid level sensors, moreover, in particular case, at least one part of the liquid level sensor (165, FIG. 1) can be fixed in the housing (110, FIG. 1), and the other part of such a sensor can be inside the original container (210, FIG. 2), and the liquid level sensor (165, FIG. 1) can be immersed in the liquid (220, FIG. 2). Also, it is worth noting that, in the particular case, the liquid level sensor (165, FIG. 1) may be part of the intake hose (235, FIG. 2) or may be mounted on such an intake hose (235, FIG. 2). It should be noted that in the particular case when installing (in particular fixing) a liquid level sensor (165, FIG. 1) in the housing (110, FIG. 1) of the device (100, FIG. 1) such a liquid level sensor (165, FIG. 1) can be installed above (in particular, opposite) openings (260, FIG. 2) in the housing (110, FIG. 1) of the device (100, FIG. 1) and openings (265, FIG. 2) in the original container ( 210, FIG. 2). In the particular case of the implementation of the liquid level sensor 165 by an ultrasonic sensor, the error of such a sensor is 1 centimeter. The amount, in particular, the volume (V), liquid (210, FIG. 2) height (h), in this case, one centimeter in the original container (210, FIG. 2), which is a cylinder (for example, a cylindrical barrel) with radius (R), in this case equal to 280 millimeters, can be calculated by the formula V = πR ² h (the volume of the liquid is equal to the product of the Pi number by the square of the radius and the height of the liquid level) and is 0.246 liters.

- a speaker (170, FIG. 1), which reproduces sounds when the user presses the device 100 of the described buttons, during the countdown, when it stops (in particular, turns off) or the device 100 switches to one of the described modes. In a particular case, the speaker (170, FIG. 1) is a piezoelectric speaker (piezoelectric element), an electrodynamic loudspeaker, or it can be any other sound reproducer, in particular, a means (in a particular case, a device) of reproducing sounds.

- a button for turning on the liquid supply (291, FIG. 2) and a button for turning off the liquid supply (292, FIG. 2), which start the supply and end of the liquid supply from the source tank (210, FIG. 2) to the target tank (105, FIG. .2) by means of a pump (115, FIG. 1), the turning on and off of the liquid supply by the pump 115 is carried out through the relay of the pump and fan 145.

- a button for increasing the liquid supply (295, FIG. 2) and a button for decreasing the liquid supply (296, FIG. 2), which increase the amount of liquid supplied (in liters) and reduce the amount of liquid supplied (in liters) by means of a pump (115, FIG. 1), and the signal from such buttons is transmitted to the computing module 140, which converts such signals in order to change the amount of liquid that the pump 115 must transfer from the source tank 210 to the target tank 105.

- button on and off the device (298, FIG. 2), when pressed, the “power” (voltage) is supplied to the power supply unit (135, FIG. 1) of the device (100). In the particular case, the on / off button of the device (298, FIG. 2) can be a toggle switch with the “On” and “Off” positions.

- a tilt and shock sensor (195, FIG. 1), which allows registration of such effects on the device (100, FIG. 1), as the fact of the tilt of the described device (100, FIG. 1) and the fact of the impact on the described device (100, FIG. 1). In a particular case, the tilt and shock sensor (195, FIG. 1) is a gyroscope and (or) an accelerometer, or any other analogue of the tilt and shock sensor (tilt / shock). So, for example, such a tilt and shock sensor (195, FIG. 1) may be a sensor GY-BI160. The tilt and shock sensor (195, FIG. 1) is connected to the computing module (140, FIG. 1), and the readings (measurement results, signals, data, etc.) of the tilt and shock sensor (195, FIG. 1) are transmitted to the computing module (140, FIG. 1), in which the program of the computing module (320, FIG. 3) processes such indications, in particular with the aim of transferring the device 100 to one of the operating modes of the device 100, as well as with the aim of adjusting measuring the amount of liquid 220 in the initial tank 210 by the liquid level sensor 165. It should be noted that the liquid level the bones 200 (in particular, the amount of liquid 220) in the original container 210 is determined depending on the readings of the liquid level sensor 165 according to one of the known formulas, and this formula can also take into account the correction (in particular, at least one coefficient) to determine the level ( and (or) the volume) of liquid 220 depending on the readings of the tilt and shock sensor (195, FIG. 1), in particular, depending on the slope of the original tank 210 and device 100.

In FIG. 3 shows a general diagram of the elements of the device, the relationships and interactions between them.

It is worth noting that the device 100 can operate in three modes: “operation mode”, “standby mode” and “lock” mode, which are described in more detail below.

The following describes an example of the operation (operation) of the device 100 in the "operation mode".

The device 100 is turned on by supplying voltage to the power supply unit 135 after the user presses the on / off button of the device 298.

Next, the power supply unit 135 converts the voltage supplied to it of 220 volts to the required voltage to power the constituent elements of the device 100, as described in the framework of the present description (for example, 5 volts, 12 volts, 24 volts, etc.), and feeds voltage to the relay of the charge and power regulator (180) and the relay of the charge and power regulator (180).

It is worth noting that the relays of the charge and power regulator (180) and the relays of the charge and power regulator (180) are connected to the computing module 140 via a (control) cable (in particular, at least one wire, a bundle of wires, etc.) or through one of the known methods and devices for connecting (in particular, connecting) electrical components (in particular, elements), and this type of connection (in particular, connecting) is applicable within the framework of the present description of the device 100 to all the constituent elements (parts) of the described mustache roystva 100 and the connections between them.

Then, by means of the relay of the charge and power regulator (180), the battery 185 is charged. If the power supply unit 135 does not supply voltage to the elements (in particular, computing module 140, pump 115, sensors, etc.) of the described device 100, for example, if there is no 220 V network voltage, the rechargeable battery 185 supplies the necessary voltage to the mentioned elements of the device 100, in particular the voltage necessary for the functioning (operation) of such elements of the device 100.

Then, through the relay of the charge and power controller (180), voltage is supplied to the computing module 140 and to the communication module 150.

Next, the program of the computing module 320 is loaded on the computing module 140 and to the information display module 175 by means of the computing module 140 (in particular, by the means of the program of the computing module 320), a message is sent about loading the program of the computing module 320, for example, “Loading ...”, “ The software of the computing module is loading ... ”, etc. Moreover, the program of the computing module 320 processes (in a particular case, conversion) the signals (and / or data, information, etc.) received by the computing module 140 from the described sensors and other elements (in particular, the components of the device 100), and also transmitting (in the particular case, sending) data and / or signals (in particular, control signals) to the described sensors and other elements of the described device 100 and (or) the components of the computing module 140 (for example, microcircuits that are part of the calculation illustrative module 140, processors, microprocessors, etc.).

Then, on the communication module 150, the software of the communication module 150 is downloaded and the software of the communication module 150 is registered on the network (in particular, in the operator’s network (mobile, cellular, satellite, etc.)) and a greeting message is displayed on the information display module 175 , in particular, containing data (for example, in a text or graphic format for presenting data) about the current mode of the device 100, in particular (Operation mode), the current balance of liquid 220 in the initial tank 210, defined (in particular, fixing ovannymi) liquid level sensor 165), the amount of liquid 220 transferred (pumped, spilled, etc.) through the pump 115 to the target tank 105 from the original tank 210 for the last time the transmission (spill, etc.), which also includes information (data) about the need for the user of the device 100 to indicate the amount of liquid transferred in liters (carried out by means of the button for increasing the fluid supply 295 and the button for decreasing the liquid supply 295) or the need for the user of the device 100 to press the power button under Achi fluid 291.

Next, a message is sent to the server through the communication module 150, and such a message may include:

- The state of the device 100, in particular, the described modes (operations) of the device 100, as well as the name or identifiers, for example, the identification number, ID of at least one of the described sensors, if it was detected that such a sensor (in particular, the readings of which caused (led to) blocking of the device 100 or its transfer to one of the described modes (operation) of the device 100). It should be noted that in the particular case, the state of the device 100 shows (describes, determines, etc.) the reason for changing the operating mode of the device 100;

- The charge level of the battery 185, transmitted to the computing module 140 and processed by the program of the computing module 320;

- The value of the fluid flow sensor 125, in particular the (current) indicators of the fluid flow sensor 125, converted into liters by the computing module 140 through the program of the computing module 320, and the amount of liquid transferred from the source tank 210 to the target tank 105 by the pump 105 from the moment the beginning of the supply (in particular, strait, pumping, etc.) of the liquid 220 by the pump 115;

- The value of the liquid level in the original tank 110, recorded and transmitted to the computing module 140 by the liquid level sensor 165, and the computing module using the program of the computing module 320 can convert the readings of the liquid level sensor 165 into liters by using the known formulas for converting the sensor readings into liters (in in particular, in the amount of liquid remaining in the original container 210), where the formula is written in program code;

- An identifier for turning on or off, in particular, buttons for turning on the liquid supply 291 and (or) buttons for turning off the liquid supply 292 described above;

- GPS coordinates of the device 100, determined (fixed) by the communication module 150, transmitted by the communication module 150 to the computing module 140.

Next, a sound signal is reproduced by means of a speaker 170 informing (notifying) the user about the readiness of the device 100 for operation.

It is worth noting that the program of the computing module 320 is executed in a cyclic mode (period), interrogating the elements of the device 100, in particular, elements such as a communication module 150, an information display module 175, a power supply on / off button 291, a fluid off button 292, and buttons increase fluid flow 295, buttons to reduce fluid flow 296, tamper sensor 130, fluid level sensor 165, fluid flow sensor 125, tilt and shock sensor 195, speaker 170. The battery charge level is also determined battery 185. It is worth noting that the data received from the aforementioned elements of the device 100 is sent through the communication module 150 to the server with a predetermined (predetermined) frequency (which is programmed in the program of the computing module 320, for example, by the developer (eg, programmer) or the user of the device 100 ), for example, such mentioned data can be sent to the server with a frequency of once a minute, once every five minutes, once every thirty minutes, etc.

In the particular case, upon receipt of a signal by the computing module 140 about the absence of power (voltage) supplied (which is supplied) to the power supply unit 135 (and power (voltage) is supplied to the battery 185, i.e., the battery (s) are charged (ka) 185 ), the device 100 goes into standby mode (in the particular case, in this mode, the device 100 expects the supply of power (voltage) to the battery 185 and power from an external source, in particular, from a (electrical) network voltage of 220 volts), which is described in more detail described later.

When the tamper sensor 130 and (or) the tilt and shock sensor 195 are triggered, and also if the volume of liquid (detected by the liquid level sensor 165) in the initial tank 210 is less than a predetermined value (for example, less than one, two, five, etc. liters, moreover, such a volume of liquid is determined, in a particular case, is calculated (calculated, etc.) by the program of the computing module 320, in particular, depending on the limit (maximum, etc.) value for the said sensor), and also if through the sensor fluid flow rate 125 is not carried out by fluid supply (i.e., the signal from the fluid flow sensor 125 is not supplied to the computing module 140), or a change in GPS coordinates was detected by the communication module 150 (the location of the device 100, in particular its geographical coordinates), then the device 100 switches to blocking, which is described in more detail below. It is worth noting that the communication module 150 sends data to the server about the remaining amount (in particular, volume) of the liquid registered by the liquid level sensor 165.

In the particular case, the spill (pumping, transfer of fluid through the pump 115) of the liquid 220 from the source tank 210 to the target tank 105 can be carried out by the device 100 as indicating by the user of the device 100 the amount (in particular, volume) of the liquid 220 necessary for the spill (in particular (pumping) from the source tank 210 to the target tank 105, and without the user of the device 100 indicating the amount (in particular, volume) of liquid 220 needed to spill (in particular, pumping) from the source tank 210 to the target tank 105.

In the case of interaction (operation) of the user of the device 100 with the device 100 indicating the amount of liquid necessary for the spill (in particular, pumping by pump 115) from the source tank 210 to the target tank 105, the user of the device 100 presses the fluid supply enable button 291. Next, on the display module To information 175, a countdown message is displayed (for example, “Before the start of the spill, 5 seconds remain”, “Before the start of the spill, 4 seconds remain”, etc., or “Countdown: 5 seconds”, “Countdown” : 4 seconds ”,“ Countdown: 3 seconds ”,“ Countdown: 2 seconds ”,“ Countdown: 1 second ”,) before the spill of liquid 220 from the source tank 210 to the target tank 105 through the pump 115. It should be noted that the mentioned countdown to the beginning of the spill of liquid is implemented by the program of the computing module 320, in particular, by a software timer. It is also worth noting that countdown messages may be accompanied by a speaker 170 playing sound signals. Then, at the end of the countdown, the computing module 140 provides a control signal (in particular, a voltage of a certain value from the computing module 140) to the pump and fan relay 145, which turns on the fan (cooling) 155 (for cooling the elements of the described device 100) and pump 115 ( for the implementation of the spill (pumping, pumping, transfer, etc.) of liquid 220 from the source tank 210 to the target tank 105). Strait (supply, pumping) of liquid 220 is carried out by pump 115 from the initial tank 210 to the target tank 105, during which the current display of the liquid level sensor 165 is displayed on the information display module 175 (moreover, such indicators are converted by the software of the computing module 320 into the quantity in particular, the volume of liquid 220 remaining in the original container 210) and a liquid flow sensor 125 (moreover, conversion is performed by the software of the computing module 320 such indicators in quantity, in particular, volume, liquid 220 remaining in the original tank 210). To stop the spill (pumping, transfer) of liquid 220 by the pump 115 from the source tank 210 to the target tank 105, the device user presses the fluid shutdown button 292, as a result of which the computing module 140 supplies a control signal to the pump and fan relay 145, which turns off the fan ( cooling) 155 and pump 115. Next, a message is sent to the server to the server (as described above) through the communication module 150. Next, on the information display module 175, a message about the current state (in particular mode) of the described device 100, i.e. that the current state of the device 100 is “Off”, after which the greeting message described above is displayed, after which the user of the device 100 can continue interacting with the device 100, for example, start the process of spilling (pumping, pumping, transferring) liquid 220 from the original tank 210 to the target tank 105, as described above. The device 100 is turned off after (user) pressing the on / off button of the device 298.

In the case of interaction (operation) of the user of the device 100 with the device 100 indicating the amount of liquid necessary for the spill (in particular, pumping by pump 115) from the source tank 210 to the target tank 105, the user of the device 100 selects (sets, sets) the required amount (in in particular, the volume) of the liquid (which will be spilled (transferred) from the source tank 210 to the target tank 105 by the pump 115) by using the aforementioned user to increase the fluid supply 295 and press the fluid supply 296 (moreover, the signals from the above-mentioned buttons are transmitted to the computing module 140 and processed by such a module in order to determine the amount (in particular, the volume) of the liquid that must be transferred from the source tank 210 to the target tank 105, and the required amount of liquid for transmission (pumping, strait, pumping, etc.) by the pump 115 is stored in the data storage of the computing module or its associated data storage, where the data storage can be RAM, ROM, memory card, hard drive magnetic disks, etc., whereby the stored amount of fluid for data transfer is compared with the amount of fluid transferred from the beginning of pressing the fluid supply button 292) to increase or decrease the amount (in particular, volume) of fluid from the source tank 210 to the target tank 105, respectively, and the selected (predetermined, installed) amount (in particular, volume) of liquid by the user of the device 100 is displayed on the information display module 175. It should be noted that the process of selecting the amount (in particular, volume ma) the liquid that will be spilled (transferred, overfilled, pumped, pumped, etc.) by the pump 115 is accompanied by the playback of sound signals by the speaker 170, in particular, the sound signal is produced by the speaker 170 each time the user of the device 100 presses the increase fluid supply button 295 either to the button for decreasing the flow of liquid 296, or after the user of the device 110 stops interacting (in particular, pressing) with the button for increasing the flow of liquid 295 or the button for decreasing the flow of liquid 296. Further, the user atel apparatus 100 presses a button on the fluid supply 291. Further information on the display unit 175 is performed on the message display countdown as described above. It is also worth noting that the countdown messages may be accompanied by the speaker 170 playing sound signals, as described above. Then, at the end of the countdown, the computing module 140 provides a control signal to the pump and fan relay 145, which turns on the fan (cooling) 155 (for cooling the elements of the described device 100) and pump 115 (for the implementation of the spill (pumping, pumping, transmission, etc.) e.) liquid 220 from the source tank 210 to the target tank 105). Strait (supply, pumping) of the amount of liquid 220 indicated by the user of the device 220 is carried out by the pump 115 from the source tank 210 to the target tank 105, during which the current display of the liquid level sensor 165 and the liquid flow sensor 125 are displayed on the information display module 175. When the value is reached the amount of spilled (transferred, pumped, etc.) by the pump 100 previously indicated by the user of the device 100 (in particular, data from the liquid flow sensor 125 are transmitted to the computing module 140 and (not intermittently) are compared with the stored value of the amount of liquid that must be spilled, and if the amount of liquid that must be transferred (spilled, etc.) and the amount of liquid transferred (spilled, etc.) the pump 115 stops), the control signal is transmitted to the pump and fan relay 145 and the pump 115 is turned off (thereby stopping the transfer of liquid (spill, supply, pumping, etc.) by the pump 115) and the fan (cooling) is turned off 155. Next, the computational meter dulem 140 through the communication module to the server message is sent to the server (as described above). Next, on the information display module 175, a message about the current state of the described device 100 is displayed, i.e. that the current state of the device 100 is “Off”, after which the greeting message described above is displayed, after which the user of the device 100 can continue interacting with the device 100, for example, start the process of spilling (pumping, pumping, transferring) liquid 220 from the original tank 210 to the target tank 105, as described above. The device 100 is turned off after (user) pressing the on / off button of the device 298.

In the aforementioned “standby” mode on the information display module 175, a message is displayed indicating the need to connect power to the device 100 (apply voltage to the device 100), for example, in the form “Connect the power. Standby mode". Next, the computing module 140 sends a message to the server to the server (as described above) through the communication module 150. The message is sent at a predetermined frequency, which is programmed (set) in the program of the computing module 320, for example, by a developer (in particular, a programmer) or a device user 100, for example, sending said message once every five minutes, ten minutes, etc. At a certain minimum (residual) charge level of the battery (which is transmitted from the relay of the charge and power regulator 180 to the computing module 140) 185, for example, at 10 (15, 12, 14, etc.) percent, by means of the computing module 140 putting the device 100 in the "lock mode" and the computing module disables (shuts down) the information display module 175.

In the above-mentioned “lock mode”, the computing module 140, through the information display module 175, displays a message about the need for the user of the device 100 to contact the service center, for example, “Contact the service. Lock mode. " Then, the computing module 140 sends a message to the server to the server (described above) through the communication module 150. Moreover, it is worth noting that the mode of the device 100 can be polled from the server, in particular, by means of wired or wireless communication methods and devices (in particular, connections, etc.), and (or) translation (switching) of the device 100 into one of the mentioned modes, for example, by means of a graphical interface (user) or a text interface on the server, as well as disconnecting (in particular Resetting values (parameters, etc), at least one of the described sensors and the server is carried out also with the ability to send signals (particularly, control signals) of at least one of the elements of the disclosed device 100.

It is worth noting that in the particular case between the device (100) and the original capacity 210, a shock-absorbing pad of any known material, for example rubber, including porous, can be used. Also, such a cushion pad can be used between the pump 115 and the lower part of the housing 110 of the device 100. It is also worth noting that the cushion pad has holes corresponding to the holes in the original container 210 and the device 100, and the diameter and cross-section of such holes may differ from these holes , for example, with the aim of (additional) fixing the intake hose (235, FIG. 2) in the hole 275.

It is also worth noting that the server mentioned in the description can display (in particular, through a graphical or text user interface) the data (including messages) transmitted to it from the device 100, as well as control the device 100, in particular, the modes of the device 100 (in particular, through a graphical or text user interface), for example, by sending data that can be received by the communication module 150 and transmitted to the computing module 140 for conversion I for the component parts (elements) of the device 100.

In FIG. 4 shows one of the options for the appearance of the described device, in particular a fan (cooling) 155, connecting the device 100 to the mains via the power cable, as well as the buttons described above.

In FIG. 5 shows one of the options for the appearance of the described device from above, in particular, the upper part (which can be realized by a cover) of the device 100, on which the buttons described above are located.

Claims (38)

1. A device for transmitting and metering liquids, containing - a pump configured to transfer from a source tank of liquid supplied to the pump inlet to a target tank from the pump outlet; - an intake hose immersed in the source container and configured to pump the liquid from the source tank with the aim of transferring it to the target tank; - the outlet pipe of the pump, made with the ability to carry out the transfer of fluid by the pump to the target tank; - a liquid flow meter, configured to measure the amount of liquid transmitted by the pump from the source tank to the target tank; - a tilt and shock sensor, configured to record the fact of tilting the device and the fact of an impact on the device; - tamper sensor, configured to monitor the fact that the device is on the original capacity; - a liquid level sensor configured to measure the amount of liquid in the original container; - a fan configured to cool the device; - a power supply unit configured to supply voltage to the device; - a battery, configured to supply voltage to the device in the absence of voltage from the power supply; - information display module, configured to display the status of the device; - a speaker configured to play sounds when interacting with the device and changing the state of the device; - a button for turning on the fluid supply, configured to carry out to start transferring fluid by the pump from the source tank to the target tank; - button to turn off the fluid supply to end the transfer of fluid by the pump from the source tank to the target tank; - a button for increasing the supply of liquid to increase the amount of liquid transferred through the pump from the source tank to the target tank; - a button for reducing the fluid supply to reduce the amount of fluid transferred by the pump from the source tank to the target tank; - button on and off the device; a pump and fan relay configured to supply voltage to the fan and pump; - a relay for charging and power, configured to supply voltage from the battery to the device in the absence of voltage from the power supply; - a communication module configured to transmit data from the device to the server; - a computing module configured to monitor, control and operate the device, as well as receive signals from the tilt and shock sensor, tamper sensor, liquid level sensor, liquid flow meter, and also receive signals from the pump and fan relay (cooling) and the relay of the charging and power regulator and to send signals to the said relays, as well as to receive signals from the communication module and to transmit signals and data to the said module links for further delivery to the server; at the same time, a liquid flow meter, tilt and shock sensor, tamper sensor, liquid level sensor, information display module, speaker, fluid supply enable button, fluid supply increase button, device on and off button, pump and fan relay, charge and power control relay , the communication module is configured to connect to a computing module. 2. A device for transmitting and recording liquids according to claim 1, characterized in that the pump is an electric pump. 3. A device for transmitting and recording liquids according to claim 1, characterized in that the pump is an oil pump. 4. A device for transmitting and recording liquids according to claim 1, characterized in that the pump is an electromechanical pump. 5. A device for transmitting and recording liquids according to claim 1, characterized in that a liquid flow meter is installed between the inlet of the pump and the intake hose. 6. A device for transmitting and recording liquids according to claim 1, characterized in that the liquid flow meter is part of the pump. 7. A device for transmitting and recording liquids according to claim 1, characterized in that a liquid flow meter is installed between the pump outlet and the pump outlet. 8. A device for transmitting and recording liquids according to claim 1, characterized in that the communication module is a GSM / GPS module. 9. A device for transmitting and recording liquids according to claim 1, characterized in that the communication module includes a SIM card. 10. A device for transmitting and recording liquids according to claim 1, characterized in that the opening sensor is a reed switch. 11. A device for transmitting and recording liquid according to claim 1, characterized in that the liquid level sensor is an ultrasonic range finder. 12. A device for transmitting and recording liquids according to claim 1, characterized in that the speaker is a piezoelectric speaker. 13. A device for transmitting and recording liquids according to claim 1, characterized in that the information display module is a liquid crystal monitor. 14. A device for transmitting and recording liquids according to claim 1, characterized in that the on and off button of the device for transmitting and metering liquids is a toggle switch. 15. A device for transmitting and recording liquid according to claim 1, characterized in that the communication module is configured to determine the geographical coordinates of the location of the device. 16. A device for transmitting and recording liquids according to claim 1, characterized in that a refueling gun is connected to the pump outlet.

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