RU175121U1 - PRIMARY CONVERTER OF A PIEZER RESONANT VISCOUS VACUUM METER - Google Patents

Abstract

The utility model relates to the field of vacuum gauges and is intended to measure gas pressure in the range from 0.1 to more than 101,000 Pa. The essence of the utility model is that in the primary signal converter, a standard tuning fork type quartz resonator in a cylindrical housing with a gas passage is used as a sensor. The resonator housing, in turn, is used to mount the resonator in the block. The primary converter is made in the form of a single collapsible metal structure containing a flanged vacuum inlet, a converter housing, a housing cover, a clamping nut, a temperature sensor, an electronic circuit of a generator and a primary signal shaper. Technical result: manufacturability and cheaper manufacturing of the device, including due to the availability of standard quartz resonators, increasing the efficiency of thermal compensation of the output signal of the converter by minimizing temperature-controlled volume, more effective protection from electromagnetic and electrostatic interference of the electronic circuit of the converter. 3 ill.

Description

The device belongs to the field of vacuum gauges and is intended to measure the total gas pressure in the range OD - more than 101 000 Pa and can be used to measure the pressures of discharged gases and gases with a pressure more atmospheric as part of the device and as a separate unit in industrial and laboratory conditions, in automatic systems control system (ACS) of vacuum devices, in emergency shutdown systems, control of vacuum-technological processes.

Known vacuum gauges usually contain a sensor and an electronic signal processing unit with an indicator of indications, while by design they are divided into monoblock and with a remote sensor unit or a remote sensor unit with a primary converter. In monoblock vacuum gauges, the sensor, signal converter and indicator are located in a single housing. For example, a wide-range vacuum gauge (Televac (USA). Operation manual for the SS-10 vacuum gauge; http://www.televac.ru) the primary transducer of which is made as a single unit with a flanged vacuum inlet and contains two sensors: inverse magnetron with a cold cathode, with a measurement in the high vacuum range and a piezoresonance-viscous quartz sensor with a measurement in the range of medium and low vacuum. However, this vacuum gauge uses a special large quartz resonator, which, along with the complex design of the unit, increases the cost of manufacturing and using the vacuum gauge, especially in cases where a quartz resonator is required to be replaced.

Known combined vacuum gauge (US Pat. 4995264) for measuring gas pressures in the low and medium vacuum ranges with the ability to compensate for errors associated with the composition of the gas or molecular weight of the gas. The primary converter unit of the known vacuum gauge comprises in a common housing a flange vacuum input, an electronic circuit of the converter, a thermoresistive vacuum sensor and a piezoresonant quartz sensor. However, in the known converter, a special tuning fork type quartz resonator is used and its fastening to the block is made at the base of the resonator with electrode leads, using electrical insulating adhesive, which makes this design non-separable, reduces the thermal compensation efficiency, especially during uneven heating, and increases the complexity and cost of manufacturing the device.

A piezoresonance vacuum gauge is known (Μ. Ono, M. Hirata, K. Kokubun, Η. Murakami, F. Tamura, Η. Hojo, Η. Kawashima, Η. Kyogoku, "Desing and performance of a quartz oscillator vacuum gauge with a controller" , J. Vac. Sci. Technol. A. 3 (3), pp. 1746-1749 (1985)) comprising a remote unit with a standard resonator and a separate processing and display unit. However, in this device, the resonator is fixed separately from the block body; the location of the thermocompensating elements and the generator circuit are not considered. Closest to the claimed device is a combined wide-range vacuum gauge (US Pat. No. 4,747,311) containing an ionization vacuum sensor used for measuring in the high vacuum range and a piezoresonant quartz sensor for measuring in the low and medium vacuum region. The quartz resonator used in this vacuum gauge has a protective case with a hole for the passage of gas and is fixed in the block due to the conclusions of the resonator electrodes. An electronic circuit for processing the signals of two sensors and an indication indicator are located in the vacuum gauge case. However, the known vacuum gauge does not stipulate the possibility of using standard quartz resonators. The electronic signal processing circuit and the indicator located in the block contain all the electronic elements for converting and processing the primary signal, which increases the block size and, in turn, reduces the accuracy of the temperature control of the piezoresonance sensor and temperature-sensitive elements of the electronic circuit, thereby reducing the efficiency of temperature error compensation the primary signal of the piezoresonance sensor. Thus, the design of the known vacuum gauge is not optimal in relation to the compensation of temperature error, manufacturability and manufacturing cost, as well as the possibility of replacing the piezoresonance sensor.

The objective of the proposed utility model is to reduce instrumental errors and costs for the manufacture and operation of the device through the use of a standard quartz resonator, the optimal method for attaching it and reducing the size of the primary signal converter.

Low-frequency tuning-fork type quartz resonators with bending vibrations in length are electronic components widely used in electronic devices to stabilize the reference frequency of various generators. (Reference on quartz resonators / Androsova V.G., Banks V.N., Dikidzhi A.N. et al .; Edited by P.G. Pozdnyakov. - M.: Communication, 1978.-288 p). Massively produced and available in electronic components stores at a low price (10-20 p / pc.) (Http://www.quartzl.ru Quartz store catalog. Radio parts.). The resonant frequency range of these resonators is 30-150 kHz. The most common are the so-called “clock” resonators with a resonant frequency of 32768 Hz, used to generate signals with a 1-second oscillation period in real-time measuring devices. A standard tuning fork type quartz resonator 1 (Fig. 1), contains external wire leads 2 of the resonator electrodes 6 for connecting to an external electric circuit, a ceramic pouring mass 3 for connecting and attaching a quartz tuning fork resonator 6 with a metal base 4, a cylindrical metal housing 7 connected vacuum tight with base 4, quartz tuning fork 6 with sprayed, film electrodes 5.

The measuring principle of the proposed piezoresonance-viscous transducer is based on a change in the dynamic resistance or impedance of the resonator during vibration damping in a gas due to viscous or molecular friction (On. Ono, M. Hirata, K. Kokubun, Η. Murakami, Η. Hojo, Η. Kawashima , Η. Kyogoku, "Quartz friction vacuum gauge for pressure range from 0.001 to 1000 Torr", J. Vac. Sci. Technol. A. 4 (3), pp. 1728-1731 (1986)). The main instrumental errors of the converter are the temperature error of the resonator and temperature-sensitive elements of the electronic circuit, the error associated with electromagnetic and electrostatic interference and the error associated with uncontrolled changes in the capacitance of the resonator-connection line-generator system, in particular when the cavity is displaced relative to the generator or external influences to this system. The temperature error of the resonator is associated with the fundamental dependence of the resonator impedance on temperature and is compensated with the help of temperature sensors or by manufacturing a resonator with a less thermally dependent crystallographic slice (Pat. EP 0233054). The remaining errors are compensated or eliminated, respectively, using thermal sensors, shielding and optimization of the design of the device.

The design with a standard quartz resonator fixed in a metal flange vacuum inlet and used in the proposed primary converter is shown in Fig. 2 and consists of a standard quartz resonator 1 inserted into a hole of a metal flanged vacuum inlet 10 and fixed by fusible metal solder 9 along the diameter of the resonator body. In the housing of the resonator there is an opening for the passage of gas 8.

The design of the inventive primary transducer of a piezoresonance-viscous vacuum gauge is shown in Fig. 3 (circled by a dotted line). The proposed primary converter Fig. 3 consists of a standard quartz resonator 1 with a hole in the gas passage fixed with a metal fusible solder 9 in a vacuum flange inlet 10, screwed onto the flange inlet of the converter housing 12, screwed onto the cover converter housing 13, screwed onto vacuum input of nut 11 for fastening to the housing of the device or another base 16, the circuit of the generator and the driver of the primary DC signal 14 located inside the housing and 12, the temperature sensor 15 soldered by fusible metal solder 9 to the flange vacuum inlet 10.

The proposed primary signal converter can be used as a block in a piezoresonance-viscous vacuum gauge, in which there is a secondary converter containing at least a signal amplifier, a signal linearizer and an indication indicator. It is possible to use the proposed converter, supplemented by an amplifier, as a control element of automation or ACS.

The proposed device operates as follows. When the gas pressure inside the vacuum inlet changes, the resonator impedance changes, which leads to a change in the current of the primary output signal generated by the electronic circuit of the generator and signal conditioner. When the temperature of the converter changes, effective compensation of the temperature error of the resonator and the electronic circuit of the signal conditioner is facilitated by the relatively large size and mass of the metal block of the converter having a high heat capacity and thermal conductivity. In this case, the converter unit performs the function of a thermostat or thermostabilizer, reducing temperature gradients inside the unit. In this case, the arrangement of the resonator, the electronic circuit, and the temperature sensor is such that they are at a minimum distance from each other, and the resonator and the temperature sensor are attached to the metal elements of the block using a metal solder, which also has high thermal conductivity, which in total increases the accuracy of controlling the temperature of the resonator and block as a whole. In the presence of external electromagnetic and electrostatic interference, the location of the sensitive elements - the resonator and the generator circuit inside the metal block is the most effective solution for shielding from this type of interference. When the device is operating, the line connecting the generator to the resonator is very sensitive to mechanical vibrations and displacements, since it also has a capacitance and inductance, the change of which affects the equivalent parameters of the resonator. To eliminate such random interference, the line connecting the resonator and generator is made as short as possible. In the proposed device, the connection line is minimized as much as possible.

An additional advantage of the design of the proposed converter is the possibility of its relatively quick disassembly for replacing the resonator, circuitry or cleaning the internal surfaces of the vacuum inlet from contamination.

Claims (1)

A piezoresonance-viscous vacuum gauge primary transducer comprising a quartz resonator, an electronic signal conversion circuit, a vacuum inlet, characterized in that a standard quartz resonator is used in a metal casing with a gas passage, the cylindrical casing of which is used to mount the resonator in a vacuum inlet using metal solder and the primary converter unit is made in the form of a collapsible design containing a vacuum inlet, a converter housing, a housing cover a mustache, a nut fastening to the body of the device, an electronic circuit of the generator and driver of the primary DC signal, and a temperature sensor fixed with a metal solder to the vacuum inlet.

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