RU2307332C1 - Micro-barograph - Google Patents

Abstract

FIELD: instrument industry.

SUBSTANCE: micro-barograph comprises basic assembling frame, barometric sensor suspended in the frame by means of a lever, counterweight, photoelectric converter made of a differential photoelectric cell connected with the controller, and light diode connected with the power source. The first end of the measuring spring is connected with the micrometric reading device. The micro-barograph has additional assembling frame connected with the basic assembling frame. The additional assembling frame receives the suspended rocker with different arms. The short arm of the rocker is connected with the barometric sensor, and the long arm is connected with the counterweight. The first end of the compensation spring is connected with the free end of the measuring spring and the lever of the barometric sensor. The second end of the spring is connected with the rod of the additional assembling frame. The elasticity moment of the measuring spring is equal to that of the compensation spring.

EFFECT: enhanced precision.

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Description

The invention relates to geophysical instrumentation and is intended to measure atmospheric pressure in order to predict earthquakes, detect artificial disturbances in the atmosphere and study the effect of changes in atmospheric pressure on the readings of geophysical instruments and the earth's surface.

A photoelectric quartz barograph is known, containing a sensitive system frame in which a mirror with a beam is suspended on horizontally elastic threads, a hollow sealed quartz ball is welded at one end of the beam, and a brass threaded sleeve with lead nuts acting as a counterweight is fixed on the other. The frame of the sensitive system by means of horizontally arranged threads is suspended in a mounting frame rigidly connected to the body of the device. The frame of the sensitive system is connected by a lever with a measuring spring and a reading micrometer device. A photovoltaic device that converts the angular displacements of the beam into an electric signal consists of a lamp, a mirror, and a differential photocell (see Gridnev D.G., Prokhorovsky G.S. Model of a photoelectric quartz barograph // Tidal deformations of the Earth. M .: Nauka, 1975, p. 167-171).

The disadvantage of this barograph is its low sensitivity due to the lack of galvanometric registration.

The closest in technical essence to the present invention is a microbarograph comprising a main mounting frame, in which a barometric sensor made in the form of a hollow sealed ball, a counterweight made in the form of a metal screen with a rectangular hole in the center, a photoelectric converter, is suspended on elastic threads through a lever made in the form of a differential photocell connected symmetrically to the opening of the metal screen connected to the recorder, and an LED, p connected to the power supply, and a measuring spring, one end of which is connected to a micrometer reading device (AS USSR 735940, class G01L 7/22, 1980).

The disadvantage of this method is the low accuracy of the measurement due to the registration of only short-period changes in atmospheric pressure.

The technical result is to increase the measurement accuracy by increasing the angular sensitivity of the microbarograph, eliminating zero-point drift, damping the barometric sensor and arresting it during transportation.

The technical result is achieved in a microbarograph comprising a main mounting frame, in which a barometric sensor made in the form of a hollow sealed ball, a counterweight made in the form of a metal screen with a rectangular hole in the center, a photoelectric converter made in the form of symmetrically located the hole of the metal screen of the differential photocell connected to the recorder, and the LED connected to the power supply, and the meter a spring, one end of which is connected with a micrometer reading device, an additional mounting frame connected by means of a technological rod to the main mounting frame and located symmetrically to it, an uneven rocker suspended on additional elastic threads in an additional mounting frame and separated by short and long shoulders, a compensation spring installed coaxially with the measuring spring, one end of which is connected via a rod to the free end of the measuring spring and to the lever of the barometric sensor, and the other with the technological rod of the additional mounting frame, and a damping device made in the form of a hemisphere with a screw, into which the barometric sensor is installed with a gap, while the short arm of the rocker arm is connected with the barometric sensor with an elastic thread, and the long arm is with counterbalance, the differential photocell and LED are rigidly fixed to the main mounting frame by means of a rack, and the barometric sensor lever and the beam are parallel to each other a friend and in one vertical plane.

Distinctive features of the proposed microbarograph are an additional mounting frame, its connection by means of a technological rod with the main mounting frame and its location symmetrical to it, uneven beam, suspended on additional elastic threads in an additional mounting frame and separated by short and long shoulders, a compensation spring installed coaxially to the measuring spring , one end of which is connected via a rod to the free end of the measuring spring and to the barometric lever of the sensor, and the other with the technological rod of the additional mounting frame, made in the form of a hemisphere damping device with a screw, in which a barometric sensor is installed with a gap, the short arm of the rocker arm is connected with an elastic thread to the barometric sensor and the long arm is with a counterweight, fixing differential photocell and LED on the main mounting frame through the rack, the location of the lever of the barometric sensor and rocker arm parallel to each other and in one vert ical plane. This improves the accuracy of the measurement. The implementation of an additional mounting frame with an unequal rocker suspended on it, its connection through the technological rod with the main mounting frame and its symmetrical arrangement allows increasing the angular sensitivity of the microbarograph by transmitting the displacement of the barometric sensor to the short arm of the rocker and registering the displacement at the end of the long arm. The implementation of the compensation spring eliminates the zero-point drift of the barometric sensor due to the equality of the elastic moments of the measuring and compensation springs. The implementation of the damping device allows you to adjust the decay time of the oscillations of the barometric sensor. The installation of a barometric sensor in a damping device improves the quality of registration. Rigid mounting of the differential photocell and LED on the main mounting frame eliminates the influence of temperature on the measurement accuracy. The location of the lever of the barometric sensor and the rocker arm parallel to each other and in the same vertical plane increases the linearity of the readings of the microbarograph.

The microbarograph is illustrated in the drawing, which shows a General view of the device.

The microbarograph includes a main mounting frame 1, in which a barometric sensor 5, made in the form of a hollow sealed ball, a counterweight 6, made in the form of a metal screen with a rectangular hole 7, and a photoelectric converter 8, made in the form of are suspended on elastic threads 2 and 3 by means of a lever 4 located symmetrically to the hole 7 of the differential photocell 9 connected to the recorder 10, and the LED 11 connected to the power supply 12. The measuring spring 13 is connected at one end 14 with a micrometer with counting device 15. An additional mounting frame 16 is connected by means of the technological rod 17 with the main mounting frame 1 and is located symmetrically to it. The uneven beam 18 is suspended on additional elastic threads 19 and 20 in an additional mounting frame 16. The beam 18 is divided by elastic threads 19 and 20 into short 21 and long 22 arms. The short arm 21 of the rocker arm 18 is connected to the barometric sensor 5 by means of an elastic thread 23, and the long arm to the counterweight 6. The lever 4 of the barometric sensor 5 and the rocker arm 18 are parallel to each other and in the same vertical plane. Installed coaxially to the measuring spring 13, the compensation spring 24 is connected at one end 25 via a rod 26 to the free end 27 of the measurement spring 13 and to the lever 4 of the barometric sensor 5. The other end 28 of the compensation spring 24 is connected to the process rod 17 of the additional mounting frame 16. The elastic moment the measuring spring 13 is equal to the elastic moment of the compensation spring 24. The damping device 29 is made in the form of a hemisphere with a screw 30. A barometric sensor 5 is installed in it with a gap. entsirovanny photocell 9 and LED 11 are fixedly attached to the main mounting frame 1 by means of the rack 31.

The microbarograph works as follows.

At the observation point, the microbarograph with the help of set screws (not shown in the drawing) is displayed in a horizontal position. The barometric sensor 5 is disarmed, for which the damping device 29 is screwed into the base of the microbarograph with a screw 30 to provide a gap between it and the barometric sensor 5. A recorder 10 is connected to the differential photocell 9 circuit, and a power supply 12 is connected to the LED circuit 11. differential photocell circuit 9 is reduced to zero. To do this, using a micrometer reading device 15 change (increase or decrease) the tension of the measuring 13 and compensation 24 springs. The registration of atmospheric pressure variations begins. If, with increasing atmospheric pressure, the electrical signal in the circuit of the differential photocell 9 decreases, it is necessary to change the polarity of the connection of the differential photocell 9 to the recorder 10. When the atmospheric pressure increases, the electrical signal increases. The lever 4 of the barometric sensor 5 and the long arm 22 of the rocker arm 18 oscillate in antiphase. With increasing atmospheric pressure, the barometric sensor 5 will deviate upward. The short arm 21 of the rocker arm 18, suspended in an additional mounting frame 16 on the elastic threads 19 and 20, will deflect upward, and the long arm 22 - down.

The proposed microbarograph improves measurement accuracy by increasing the angular sensitivity of the microbarograph, eliminating zero-point drift, damping the barometric sensor and arresting it during transportation. The microbarograph is simple and does not require large manufacturing costs, and is durable in operation.

Claims (1)

A microbarograph comprising a main mounting frame, in which a barometric sensor made in the form of a hollow sealed ball, a counterweight made in the form of a metal screen with a rectangular hole in the center, a photoelectric converter made in the form of a differential metal screen symmetrically located on the elastic threads by a lever is suspended a photocell connected to the recorder, and an LED connected to the power supply, and a measuring spring, one end of which is connected with a micrometer reading device, characterized in that it is equipped with an additional mounting frame connected by means of a technological rod to the main mounting frame and located symmetrically to it, unequal arm, suspended on additional elastic threads in the additional mounting frame and separated by short and long shoulders installed coaxial to the measuring spring with a compensation spring, one end of which is connected via a rod to the free end of the measuring spring and to p with a barometric sensor base, and the other with a technological rod of an additional mounting frame, and a hemispherical damping device with a screw, into which a barometric sensor is installed with a gap, while the short arm of the rocker arm is connected with the barometric sensor with an elastic thread, and the long arm is with counterbalance, the differential photocell and LED are rigidly fixed to the main mounting frame by means of a rack, and the barometric lever of the sensor and the beam are parallel to each other Yeah, and in one vertical plane.