RU87254U1 - FLOWMETER (OPTIONS) - Google Patents

Abstract

1. A flowmeter containing an electric energy generator, a converter of parameters characterizing the flow of liquid into an electrical signal connected to a converter of parameters of the electric signal to a value of the flow of liquid, characterized in that an electric energy storage device connected to a converter of parameters characterizing the flow of liquid is inserted into it , into an electric signal, by a converter of the parameters of the electric signal into a liquid flow value and a wireless transceiver, interacting using a wireless communication channel with a wireless transceiver installed at the receiving center. ! 2. The flow meter according to claim 1, characterized in that the electric energy generator is equipped with a voltage stabilization unit. ! 3. The flow meter according to claim 1, characterized in that the electrical energy storage device is equipped with a voltage stabilization unit. ! 4. The flow meter according to claim 1, characterized in that the converter of the parameters of the electrical signal to the value of the fluid flow is equipped with a storage device and a real-time clock. ! 5. A flowmeter containing an electric energy generator connected to a converter of electric signal parameters to a liquid flow rate, characterized in that an electric energy storage device is connected to it, connected to a converter of electric signal parameters to a liquid flow rate and a wireless transceiver interacting via a wireless channel communication with a wireless transceiver installed at the receiving center. ! 6. The flow meter according to claim 5, characterized in that the generator is electric power

Description

The claimed utility model relates to the field of measuring fluid flow and can be used in measuring water flow in water systems.

Known, selected as the closest analogue, a flow meter containing an electric energy generator connected to, interconnected, a parameter converter characterizing a liquid flow into an electric signal and a converter of electric signal parameters to a liquid flow value (US patent No. 2221943, Cl. IPC G01F 1/08, published on 11/19/1940)

The disadvantage of this flow meter is that it is impossible to remotely record the indications of indicator devices (flow sensors), it is especially inconvenient when registering the readings of the instruments of each apartment of an apartment building. Thus, the main disadvantage of the known flow meter is the lack of centralized control of fluid flow.

The technical result that can be obtained in the claimed utility model is the creation of a flow meter, which provides centralized control over the flow of fluid.

The technical result is achieved in that in a flowmeter containing an electric energy generator, a converter of parameters characterizing the flow of liquid into an electric signal connected to a converter of parameters of an electric signal to a value of a fluid flow, an electrical energy storage device connected to a converter characterizing a flow of liquid into an electric signal, a converter of electric signal parameters in the value of fluid flow and wireless transceiver, inter using a wireless communication channel with a wireless transceiver installed at the receiving center, while either the electric energy generator or the electric energy storage device is equipped with a voltage stabilization unit, in addition, the converter of the electric signal parameters to the liquid flow rate can be equipped with a storage device and a real clock time.

And also by the fact that in the flowmeter containing an electric energy generator connected to the electric signal parameter converter to the liquid flow value, an electric energy storage device connected to the electric signal parameter converter to the liquid flow value and a wireless transceiver interacting using a wireless communication channel with a wireless transceiver installed at the receiving point, while either an electric energy generator or an electric storage device eskoy power supply voltage stabilization is provided, in addition, the electrical signal transducer parameters in fluid flow rate may be provided with a memory and a real time clock.

The claimed utility model is illustrated using the diagrams shown in FIGS. 1, 2, 3. FIG. 1 shows a first embodiment of a flow meter corresponding to a present utility model, FIG. 2 shows a second embodiment of a flow meter corresponding to this utility model, FIG. 3 and 4 are examples of the implementation of the first and second flow meter variants, respectively.

Figure 1 and 2 adopted the following notation:

- generator 1 of electrical energy;

- drive 2 electric energy;

- Converter 3 parameters characterizing the flow of fluid into an electrical signal;

- converter 4 of the parameters of the electrical signal to the value of the fluid flow;

- wireless transceiver 5;

- a wireless transceiver 6 installed at the receiving point;

- pipeline 7;

- blades 8 of the generator 1 of electrical energy;

- contact 9 mounted on one of the blades 8;

- contact 10 mounted on the inner surface of the pipeline 7;

- microcontroller 11.

The claimed flowmeter corresponding to the first embodiment of the utility model and shown in Fig. 1 consists of an electric energy generator 1 connected to an electric energy storage device 2, as well as a converter 3 of parameters characterizing the flow of liquid into an electric signal, a converter 4 of the electric signal parameters the value of fluid flow and wireless transceiver 5. Converter 3 parameters characterizing the flow of fluid into an electrical signal, pre the generator 4 of the parameters of the electric signal in the value of the flow rate and the wireless transceiver 5 are connected to the drive 2 of electric energy to receive electric power from it.

The claimed flow meter corresponding to the second embodiment of the utility model and shown in FIG. 2 consists of an electric energy generator 1 connected to an electric energy storage device 2 and an electric signal parameter converter 4 to a liquid flow value, as well as a wireless transceiver 5 connected to a drive 2 of electric energy and with a converter 4 of the parameters of the electrical signal into the value of the flow rate of the liquid, which are interconnected.

The electric energy generator 1 may consist of a stator and a rotor equipped with a means capable of performing mechanical vibrations under the influence of a moving fluid flow, which can be used as a turbine made of a set of blades mounted on a shaft. As the drive 2 of electrical energy can be used, for example, a battery or capacitor. As a converter of 3 parameters characterizing the flow of liquid into an electrical signal, a device is used that measures some flow characteristic, for example, the number of revolutions made by one blade mounted on the rotor shaft per unit time.

As a converter 4 of the parameters of the electric signal to the value of the fluid flow, a block can be used that performs calculations based on information received from the converter 3 of the parameters characterizing the flow of fluid into the electric signal (for example, information about the number of revolutions made by one blade mounted on the rotor shaft, in unit of time) or received from the generator 1 of electric energy (for example, information about the rotational speed of the rotor of the generator 1 of electric energy), and receiving the number The new value of a parameter characterizing the flow rate, for example, the volume of liquid per unit time (flow rate in the pipeline). The wireless transceiver 5 can communicate with the transceiver 6 mounted at the receiving point via a wireless communication channel. The wireless communication channel may be a radio frequency communication channel, an optical communication channel, or any other electromagnetic, wireless communication channel.

To carry out voltage stabilization, the electric energy generator 1 or the electric energy storage device 2 is provided with a voltage stabilization unit (not shown in FIGS. 1-4).

The converter 4 of the parameters of the electrical signal to the value of the flow rate is equipped with a storage device and a real-time clock (not shown in FIGS. 1-4).

Figure 3 presents an example of a specific implementation of the flow meter corresponding to the first embodiment of the utility model.

In this flowmeter device, an electric energy generator 1 is placed inside the pipeline 7, blades are installed on the rotor shaft of the generator 1. The rotor shaft of the electric energy generator 1 is located along the flow in the pipeline 7 and coincides with the axis of the pipeline 7, and the plane of rotation of the blades will be perpendicular to the direction flow movement in the pipeline 7. The electric energy generator 1 is connected to the electric energy storage device 2 located outside the pipeline 7, however, the electric energy storage device 2 can t be placed inside the pipeline 7, in a common housing with an electric power generator 1. The converter 3 of the parameters characterizing the flow of liquid into an electrical signal is made in the form of a contact 9 installed on one of the blades 8 mounted on the rotor shaft of the electric energy generator 1, and connected to a microcontroller 11, a contact 10 installed on the inner surface of the pipeline 7. Converter 4 parameters of the electrical signal in the value of the fluid flow is located outside the pipeline and is connected to the microcontroller 11 and the wireless transceiver 5, which can interact l with a transceiver 6 installed at the receiving point.

The flow meter corresponding to the first embodiment is as follows.

While in the fluid flow and under its influence, the blades 8 rotate together with the rotor shaft of the electric energy generator 1, while the electric energy is generated in the generator 1, the voltage of which is stabilized by the voltage stabilization unit located at the output of the electric energy generator 1. The electric energy generated by the generator 1 is accumulated in the electric energy storage device 2.

At the same time, the contact 9 installed on one of the blades 8, as well as the blades 8 rotates around the axis of the pipeline 7. Reaching the contact 10, motionlessly installed on the inner surface of the pipeline 7, the contact 9 comes into contact with the contact 10, while the microcontroller 11 generates and transmits to the converter 4 the parameters of the electrical signal in the value of the flow rate of the liquid one electrical pulse. The converter 4 of the parameters of the electrical signal into a flow rate value, equipped with a real-time clock, captures the time of arrival of the electrical pulse.

After a certain period of time, the contact 9 again comes into contact with the contact 10, while the microcontroller 11 generates and transmits to the converter 4 the parameters of the electrical signal in the value of the flow rate of the next electrical pulse. The converter 4 of the parameters of the electric signal into a flow rate value records the time of arrival of the next electric pulse and calculates the value of the time interval between the arrival of two pulses. Then, the converter 4 of the electric signal parameters to the fluid flow value, based on the value of the time interval between the arrival of two pulses, calculates the rotation speed of the contact 9 around the axis of the pipeline and determines the speed of the fluid flow in the pipeline 7 in the time interval between the arrival of two pulses. Further, based on the velocity of the fluid flow in the pipeline 7 and the cross-sectional area of the pipeline 7, which is known and entered into the calculation program of the converter 4 of the electric signal parameters to the liquid flow rate, the converter 4 of the electric signal parameters to the liquid flow value determines the volume of liquid passed through the pipeline 7 for the time interval between the arrival of two pulses. Data on the flow rate of the liquid in each time interval between the arrival of two adjacent pulses is entered into the memory of the converter 4 of the parameters of the electric signal in the value of the flow rate.

When monitoring the flow rate, through a wireless transceiver 6 installed at the receiving point, send a request to the wireless transceiver 5 about the current flow rate of the liquid in the form of an RF signal. The wireless transceiver 5 transmits the received request to the converter 4 of the parameters of the electrical signal in the value of the fluid flow. The converter 4 of the parameters of the electrical signal to the value of the fluid flow sends information from the storage device about the current fluid flow to the wireless transceiver 5, which transmits the received information to the wireless transceiver 6 installed at the receiving station, in the form of an radio frequency signal.

Figure 4 presents an example of a specific implementation of the flow meter corresponding to the second embodiment of the utility model.

In this flowmeter device, an electric energy generator 1 is placed inside the pipeline 7, blades are installed on the rotor shaft of the generator 1. The rotor shaft of the electric energy generator 1 is located along the flow in the pipeline 7 and coincides with the axis of the pipeline 7, and the plane of rotation of the blades will be perpendicular to the direction flow movement in the pipeline 7. The electric energy generator 1 is connected to the electric energy storage device 2 located outside the pipeline 7, however, the electric energy storage device 2 can t be placed inside the pipeline 7, in a common housing with an electric power generator 1. The converter 4 of the electric signal parameters to the flow rate of the liquid is located outside the pipeline and is connected to an electric energy generator 1 and a wireless transceiver 5, which can interact with a transceiver 6 installed at the receiving station.

The flow meter corresponding to the second embodiment is as follows.

While in the fluid flow and under its influence, the blades 8 rotate together with the rotor shaft of the electric energy generator 1, while the electric energy is generated in the generator 1, which is stored in the electric energy storage device 2, and its voltage is stabilized by the voltage stabilization unit located in the electric energy storage device 2 energy.

At the same time, information about the rotational speed of the rotor of the generator 1 of the electric energy is supplied to the converter 4 of the parameters of the electric signal in the value of the fluid flow. Based on the information received about the rotational speed of the rotor of the electric energy generator 1, the electric signal parameter converter 4 to the liquid flow rate calculates the rotation speed of the blades 8 around the axis of the pipeline and determines the velocity of the liquid flow in the pipeline 7 per unit time. Further, based on the velocity of the fluid flow in the pipeline 7 and the cross-sectional area of the pipeline 7, which is known and entered into the calculation program of the converter 4 of the electric signal parameters to the liquid flow rate, the converter 4 of the electric signal parameters to the liquid flow value determines the volume of liquid passed through the pipeline 7 for the same unit of time. Data on the flow rate of liquid in each unit of time is entered into the memory of the converter 4 of the parameters of the electrical signal in the value of the flow rate.

When monitoring the flow rate through a wireless transceiver 6 installed at the receiving point, send a request to the wireless transceiver 5 about the current flow rate of the liquid in the form of an electromagnetic signal. The wireless transceiver 5 transmits the received request to the converter 4 of the parameters of the electrical signal in the value of the fluid flow. The converter 4 of the parameters of the electrical signal to the flow rate of the liquid sends information from the storage device about the current flow rate of the liquid to the wireless transceiver 5, which transmits the received information to the wireless transceiver 6 installed at the receiving station in the form of an electromagnetic (e.g., optical) signal.

Thus, by introducing an electric energy storage device and a wireless transceiver into the flowmeter, it becomes possible to centrally monitor the flow of liquid.

Claims (8)

1. A flowmeter containing an electric energy generator, a converter of parameters characterizing the flow of liquid into an electrical signal connected to a converter of parameters of the electric signal to a value of the flow of liquid, characterized in that an electric energy storage device connected to a converter of parameters characterizing the flow of liquid is inserted into it , into an electric signal, by a converter of the parameters of the electric signal into a liquid flow value and a wireless transceiver, interacting using a wireless communication channel with a wireless transceiver installed at the receiving center. 2. The flow meter according to claim 1, characterized in that the electric energy generator is equipped with a voltage stabilization unit. 3. The flow meter according to claim 1, characterized in that the electrical energy storage device is equipped with a voltage stabilization unit. 4. The flow meter according to claim 1, characterized in that the converter of the parameters of the electrical signal to the value of the fluid flow is equipped with a storage device and a real-time clock. 5. A flowmeter containing an electric energy generator connected to a converter of electric signal parameters to a liquid flow rate, characterized in that an electric energy storage device is connected to it, connected to a converter of electric signal parameters to a liquid flow rate and a wireless transceiver interacting via a wireless channel communication with a wireless transceiver installed at the receiving center. 6. The flow meter according to claim 5, characterized in that the electric energy generator is equipped with a voltage stabilization unit. 7. The flow meter according to claim 5, characterized in that the electrical energy storage device is equipped with a voltage stabilization unit. 8. The flow meter according to claim 5, characterized in that the converter of the parameters of the electrical signal to the value of the fluid flow is equipped with a storage device and a real-time clock.