CN212363529U - Pressure transmitter - Google Patents
Pressure transmitter Download PDFInfo
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- CN212363529U CN212363529U CN202021362799.6U CN202021362799U CN212363529U CN 212363529 U CN212363529 U CN 212363529U CN 202021362799 U CN202021362799 U CN 202021362799U CN 212363529 U CN212363529 U CN 212363529U
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Abstract
The utility model relates to the technical field of pressure transmitters, and provides a pressure diaphragm which is made of elastic materials and has micro strain, a diaphragm pressure leading hole is arranged in the pressure diaphragm, and a plane circular diaphragm is arranged at the extending end of the diaphragm pressure leading hole; the strain gauge is solidified on the surface of the plane circular diaphragm, and the deformation of the plane circular diaphragm causes the resistance change of the strain gauge; the amplifying circuit board is electrically connected with the strain gauge and is used for collecting resistance signals, performing temperature compensation operation on the strain gauge and outputting amplified voltage signals; and the signal conversion circuit board is electrically connected with the amplification circuit board and is used for converting the input amplified voltage signal into a standard signal of the pressure transmitter and outputting the standard signal to external equipment electrically connected with the signal conversion circuit board. The utility model discloses the highest measuring pressure is up to 1000Mpa, bears 1000 ten thousand times 1.5 times full scale pressure cycle loading, reduces the temperature drift coefficient by a wide margin.
Description
Technical Field
The utility model relates to a pressure transmitter technical field especially relates to a pressure transmitter.
Background
The pressure transmitter is a device for converting pressure into an electric signal for control and remote transmission, and can convert physical pressure parameters of gas, liquid and the like sensed by a load cell sensor into standard electric signals (such as 4-20 mADC and the like) so as to supply secondary instruments such as an indication alarm instrument, a recorder, a regulator and the like for measurement, indication and process regulation, and the measurement precision of the pressure transmitter directly influences the stability and safety of a control system. Various pressure transmitters in the prior art have the following common problems: 1. the pressure resistance is low, the ultrahigh pressure of more than 300MPa cannot be stably measured, the overload capacity is low, and after the pressure overload influence, the pressure element is damaged and the output signal is abnormal; 2. the motion amplitude of elements such as a membrane and the like of a measuring mechanism is too large, fatigue deformation is easy to occur, the service life is short, and the long-term stability is poor; 3. the temperature drift coefficient is high, and is influenced by temperature change, so that large temperature drift can be generated, and the measurement precision is reduced.
SUMMERY OF THE UTILITY MODEL
The utility model discloses problem to existence among the prior art provides a pressure transmitter for the pressure-resistant ability that pressure transmitter exists is lower among the solution prior art, the diaphragm is easy fatigue deformation and the technical problem that the temperature drift coefficient is high.
The utility model discloses technical scheme as to above-mentioned technical problem and propose as follows:
a pressure transmitter, comprising:
the pressure diaphragm is made of elastic materials and has micro strain, a diaphragm pressure leading hole is formed in the pressure diaphragm, and a plane circular diaphragm is arranged at the extending end of the diaphragm pressure leading hole;
the strain gauge is solidified on the surface of the plane circular diaphragm, and the deformation of the plane circular diaphragm causes the resistance change of the strain gauge;
the amplifying circuit board is electrically connected with the strain gauge and is used for collecting resistance signals, performing temperature compensation operation on the strain gauge and outputting amplified voltage signals;
and the signal conversion circuit board is electrically connected with the amplification circuit board and is used for converting the input amplified voltage signal into a standard signal of the pressure transmitter and outputting the standard signal to external equipment electrically connected with the signal conversion circuit board.
According to the pressure transmitter, the opening of the diaphragm pressure guiding hole is provided with the buffer plug, and the buffer plug is arranged at the opening of the diaphragm pressure guiding hole and is detachably connected with the pressure diaphragm through the diaphragm pressure guiding hole; and the buffer plug is provided with a buffer plug pressure guide hole which penetrates through the whole buffer plug, and the buffer plug pressure guide hole is communicated with the membrane pressure guide hole.
According to the pressure transmitter, the outer side wall of the pressure diaphragm is provided with the stress blocking groove, and the stress blocking groove is used for blocking the transmission of the installation stress to the planar circular diaphragm.
According to the pressure transmitter, the outer side wall of the pressure diaphragm is provided with the process interface, and the process interface and the pressure diaphragm are of an integrated structure.
According to the pressure transmitter, the strain gauge is sintered and solidified on the surface of the planar circular diaphragm through the connecting layer, and the connecting layer is made of silicate materials.
According to the pressure transmitter, the connecting layer is coated on the pressure diaphragm by adopting the steel mesh screen printing, so that the accuracy of the coating position of the connecting layer is improved, and the coating thickness of the connecting layer is controlled.
According to the pressure transmitter, the pressure diaphragm after silk-screen printing is sintered through a multi-temperature-zone vacuum tunnel furnace to form a connecting layer, and the strain gauge is solidified on the surface of the pressure diaphragm.
According to the pressure transmitter, the pressure transmitter further comprises a shell, the pressure diaphragm is fixedly connected with the shell, a circuit board support is arranged inside the shell, and the pressure diaphragm is fixedly connected with the circuit board support;
be equipped with the bonding circuit board on the circuit board support, bonding circuit board fixed connection in on the circuit board support, just the bonding circuit board with be equipped with insulating pad between the circuit board support, insulating pad is used for protecting bonding circuit board, prevents the bonding circuit board with circuit board support produces the short circuit.
According to the pressure transmitter, the strain gauge is connected with the bonding circuit board through a lead, the lead is used for transmitting signals between the strain gauge and the bonding circuit board, the bonding circuit board is connected with the amplifying circuit board through a first contact pin, the amplifying circuit board is connected with the signal conversion circuit board through a second contact pin, and the signal conversion circuit board is connected with external equipment through an electrical connector;
the outer portion of the electric connector is fixedly connected with an electric connector, and the electric connector is connected with the shell.
According to the above, pressure transmitter, be equipped with on the bonding circuit board with the strainometer with the safety cover that the wire covered, the safety cover with bonding circuit board fixed connection.
According to above-mentioned scheme the utility model discloses, its beneficial effect lies in at least:
(1) the utility model provides a pressure transmitter, the highest measuring pressure is up to 1000Mpa, and the overload capacity of standard product reaches 3 times full scale pressure, and the burst pressure can reach 20 times at most.
(2) The utility model provides a pressure transmitter adopts the pressure sensing mode that the pressure diaphragm meets an emergency a little, avoids the risk of material fatigue deformation, has prolonged the working life of pressure diaphragm, can bear 1000 ten thousand times 1.5 times full scale pressure cycle loading.
(3) The utility model provides a pressure transmitter with pressure sensing full-bridge equivalent resistance and act as temperature element, measure more for accurate medium temperature, carry out multistage temperature compensation, reduce the changer temperature drift coefficient by a wide margin, improve measurement accuracy.
(4) The utility model provides a pressure transmitter, pressure signal and temperature signal can be gathered to the strainometer, have reduced temperature data error, and the temperature compensation effect is better.
(5) The utility model provides a pressure transmitter, simple structure, production process automation degree is high, and production efficiency is high, has realized mass production, and single set of production facility daily output can reach 3000.
Drawings
In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the description of the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.
Fig. 1 is a schematic cross-sectional structural diagram of a pressure transmitter according to an embodiment of the present invention;
fig. 2 is an enlarged schematic structural diagram of a connection portion between a pressure diaphragm and a strain gauge in the pressure transmitter according to the embodiment of the present invention;
fig. 3 is a schematic structural diagram of a pressure diaphragm in the pressure transmitter according to an embodiment of the present invention;
FIG. 4 is a schematic structural diagram of an auxiliary silicate coated on a pressure diaphragm in the pressure transmitter according to an embodiment of the present invention;
fig. 5 is a schematic structural diagram of another view angle of the auxiliary silicate coated on the pressure diaphragm in the pressure transmitter according to the embodiment of the present invention;
fig. 6 is a first flowchart of a method for manufacturing a pressure transmitter according to an embodiment of the present invention;
fig. 7 is a schematic diagram of a positioning structure of a strain gauge in a pressure transmitter according to an embodiment of the present invention;
fig. 8 is a flowchart of a second method for manufacturing a pressure transmitter according to an embodiment of the present invention.
Wherein, in the figures, the respective reference numerals:
Detailed Description
It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly or indirectly secured to the other element. When an element is referred to as being "connected to" another element, it can be directly or indirectly connected to the other element. The terms "upper", "lower", "left", "right", "front", "rear", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positions based on the orientations or positions shown in the drawings, and are for convenience of description only and not to be construed as limiting the technical solution. The terms "first", "second" and "first" are used merely for descriptive purposes and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features. The meaning of "plurality" is two or more unless specifically limited otherwise.
The technical problems that the pressure transmitter in the prior art is low in pressure resistance, a diaphragm is easy to fatigue and deform, and the temperature drift coefficient is high are solved. The utility model aims at providing a pressure transmitter, its core thought is: the pressure diaphragm 11 made of elastic material and having micro strain is adopted, the deformation of the pressure diaphragm 11 causes the resistance change of the strain gauge solidified on the pressure diaphragm, the amplifying circuit board 13 is used for collecting resistance signals, carrying out temperature compensation operation on the strain gauge 12 and outputting amplified voltage signals, and the signal conversion circuit board 14 is used for converting the input amplified voltage signals into standard signals of the pressure transmitter and outputting the standard signals to external equipment. The highest measuring pressure is up to 1000Mpa, and the device can bear 1000 ten thousand times of 1.5 times of full-scale pressure cyclic loading, so that the temperature drift coefficient is greatly reduced.
In order to make the technical problem, technical solution and advantageous effects to be solved by the present invention more clearly understood, the following description is given in conjunction with the accompanying drawings and embodiments to illustrate the present invention in further detail. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention.
Referring to fig. 1, the present embodiment provides a pressure transmitter 10, including:
the pressure diaphragm 11 which is made of high-strength elastic materials and has micro-strain is provided with a diaphragm pressure leading hole 111 in the pressure diaphragm 11, a plane circular diaphragm 112 is arranged at the extending end of the diaphragm pressure leading hole 111, and the intersection of the plane circular diaphragm 112 and the diaphragm pressure leading hole 111 is an arc surface, so that the pressure resistance of the pressure diaphragm 11 is improved, and overload fracture or permanent deformation in the measuring process is avoided.
The strain gauge 12 is solidified on the surface of the flat circular diaphragm 112, and the deformation of the flat circular diaphragm 112 causes the resistance of the strain gauge 12 to change (please refer to fig. 2).
And the amplifying circuit board 13 is electrically connected with the strain gauge 12, and the amplifying circuit board 13 is used for collecting the resistance signal, performing temperature compensation operation on the strain gauge 12 and outputting an amplified voltage signal.
And the signal conversion circuit board 14 is electrically connected with the amplification circuit board 13, and the signal conversion circuit board 14 is used for converting the input amplified voltage signal into a standard signal of the pressure transmitter and outputting the standard signal to an external device electrically connected with the signal conversion circuit board 14.
The working principle of the pressure transmitter 10 provided by the present embodiment may be as follows:
the strain gauge 12 can collect pressure signals and temperature signals, when the strain gauge 12 is under pressure, differential voltage signals can be generated to change, and the full-bridge equivalent resistance is not changed; when the strain gauge 12 is subjected to the action of temperature, the differential voltage signal is basically unchanged, and the full-bridge equivalent resistance is changed; the amplifying circuit board 13 acquires the differential voltage signal of the strain gauge 12 to obtain a pressure value, and the amplifying circuit board 13 acquires the full-bridge equivalent resistance of the strain gauge 12 to obtain a temperature value.
The amplifying circuit board 13 is internally provided with a data memory and a compensation program, the data correctness is compensated and corrected by utilizing a software algorithm, the strain gauge 12 is used for collecting multiple temperature points and multiple pressure points in the production process, the collected data is stored in the data memory, and the compensation program calls characteristic data in the data memory to perform compensation operation on the pressure transmitter 10, so that the temperature drift coefficient is reduced, and the nonlinearity is optimized. The specific implementation process may be: in the production process, the pressure transmitter 10 is applied with the ambient temperatures of-20 ℃, 25 ℃ and 70 ℃, the pressure transmitter 10 is applied with zero pressure, half pressure and full pressure at different ambient temperatures, the characteristic data such as the temperature value and the pressure value measured by the amplifying circuit board 13 are respectively recorded, and finally the recorded characteristic data are downloaded to the data memory of the amplifying circuit board 13. When the pressure transmitter 10 works, the temperature and pressure characteristic data stored in the data memory are read firstly, then the converted current pressure and temperature values are compensated and corrected according to the pressure and temperature characteristic data stored in the data memory when the pressure transmitter 10 is produced, the temperature drift error of the pressure transmitter 10 is compensated through a temperature drift coefficient interpolation algorithm, the temperature error of the pressure transmitter 10 is reduced, then the nonlinearity of the pressure transmitter 10 is corrected through a nonlinearity interpolation algorithm, and the linearity of the sensor is improved.
The external medium acts on the pressure diaphragm 11 to cause the strain area of the pressure diaphragm 11 to generate micro strain, that is, the planar circular diaphragm 112 generates micro strain, the center of the strain area generates tensile deformation, the edge of the strain area generates compression, the micro strain is transmitted to the strain gauge 12, the amplifying circuit board 13 provides an excitation power supply for the strain gauge 12, the strain gauge 12 inputs a differential voltage signal to the amplifying circuit board 13, the amplifying circuit board 13 amplifies the input differential voltage signal, and the signal output by the amplifying circuit board 13 is converted into a standard signal of the pressure transmitter through the signal conversion circuit board 14 and is output to the external equipment.
The pressure transmitter 10 provided by the embodiment has at least the following beneficial effects:
(1) the pressure transmitter 10 provided by the embodiment adopts a high-strength elastic material and an overload-resistant structure, the highest measurement pressure is up to 1000Mpa, the overload capacity of a standard product reaches 3 times of full-scale pressure, and the maximum bursting pressure can reach 20 times.
(2) The pressure transmitter 10 provided by the embodiment adopts a pressure sensing mode of micro strain of the pressure diaphragm 11, avoids the risk of fatigue deformation of materials, prolongs the service life of the pressure diaphragm 11, and can bear 1000 ten thousand times of 1.5 times of full-scale pressure cyclic loading.
(3) The pressure transmitter 10 provided by this embodiment uses the pressure sensing full-bridge equivalent resistor as a temperature measuring element to measure a more accurate medium temperature, performs multi-step temperature compensation, greatly reduces the transmitter temperature drift coefficient, and improves the measurement accuracy.
(4) According to the pressure transmitter provided by the embodiment, the strain gauge 12 can collect pressure signals and temperature signals, so that the temperature collection data error is reduced, and the temperature compensation effect is better.
(5) The pressure transmitter that this embodiment provided, simple structure, production process automation degree is high, and production efficiency is high, has realized mass production, and single set of production facility daily output can reach 3000.
Referring to fig. 1, specifically, a buffer plug 16 is disposed at an opening of the diaphragm pressure guiding hole 111, and the buffer plug 16 is disposed at the opening of the diaphragm pressure guiding hole 111 and detachably connected to the pressure diaphragm 11 through the diaphragm pressure guiding hole 111. The buffer plug 16 is used for protecting the pressure diaphragm 11, and when pulse pressure such as water hammer effect occurs in pressure measurement, the buffer plug 16 plays a role in buffering to prevent instantaneous high pressure from damaging the pressure diaphragm 11. Optionally, the buffer plug 16 is screwed with the inner side wall 111 of the diaphragm pressure guiding hole 111, so that the buffer plug 16 can be firmly connected with the pressure diaphragm 11, and the disassembly is also convenient. The buffer plug 16 is provided with a buffer plug pressure introduction hole 161 penetrating the entire buffer plug 16, and the buffer plug pressure introduction hole 161 is communicated with the diaphragm pressure introduction hole 111. Thereby, the external medium (liquid or gas) flows through the buffer plug pressure introduction hole 161 provided in the buffer plug 16 to the diaphragm pressure introduction hole 111, and the external medium enters the diaphragm pressure introduction hole 111.
Referring to FIG. 3, the center thickness of the flat circular membrane 112P is the rated pressure (unit: MPa) of the pressure transmitter test, and d is the diameter of the diaphragm pressure leading hole 111. Optionally, the center thickness T of the planar circular membrane 112 is 0.18mm to 3.5 mm. The central thickness T of the planar circular diaphragm 112 is determined by the magnitude of the measured pressure, and the greater the pressure, the thicker the central thickness T.
The diameter d of the membrane pressure guide hole 111 is 3 mm-5 mm. Alternatively, the diameter d of the diaphragm pilot hole 111 is 3.3 mm. When the pressure is applied, the flat circular diaphragm 112 is slightly strained, and is subjected to tensile deformation at the center and compressive deformation in a region d/2 (half the diameter of the diaphragm pressure-leading hole 111) away from the center.
The thickness L of the side wall of the plane circular diaphragm 112 is 3 mm-8 mm. Optionally, the thickness L of the sidewall of the planar circular membrane 112 is 3.35 mm. The side wall thickness L of the flat circular diaphragm 112 supports the central area, and the larger the value of the side wall thickness L is, the more stable the support to the center is, and the higher the stability of the pressure diaphragm 11 is.
The outer side wall of the pressure diaphragm 11 is provided with a stress blocking groove 113, and the stress blocking groove 113 is used for blocking the transmission of the mounting stress to the planar circular diaphragm 112 so as to eliminate the influence of the mounting stress on the measurement precision. The inner diameter D of the bottom of the stress-blocking groove 113 is 5mm to 15.2 mm. Alternatively, the groove bottom inner diameter D of the stress-breaking groove 113 is 7.6 mm. The smaller the groove bottom inner diameter D, the smaller the measurement error caused by the mounting stress.
Optionally, when the pressure sensor is used for measuring a low pressure, a protruding platform (not shown in the figure) is disposed at the center of the flat circular diaphragm 112 near the diaphragm pressure guiding hole 111, so as to effectively improve the linearity of the low pressure measurement.
Specifically, the lateral wall of pressure diaphragm 11 is equipped with process interface 17, and process interface 17 and pressure diaphragm 11 formula structure as an organic whole have realized not having the welding seam, need not the sealing member, have avoided revealing the risk. Optionally, the pressure diaphragm 11 and the process interface 17 are integrally machined from stainless steel rod material.
Alternatively, strain gauge 12 is sintered and cured on the surface of planar circular diaphragm 112 through connection layer 15, and connection layer 15 is made of silicate material. The micro strain generated by the pressure diaphragm 11 is transmitted to the strain gauge 12 through the connection layer made of silicate material.
Optionally, the connection layer 15 is silk-screened on the pressure diaphragm 11 by using a steel mesh 18, so as to improve the accuracy of the coating position of the connection layer 15 and control the coating thickness of the connection layer 15. Referring to fig. 4 and 5, the pressure membrane 11 is fixedly placed on the base 27, the prepared steel mesh 18 is covered on the pressure membrane 11, then silicate is coated on the pressure membrane 11, and the silicate is coated on the pressure membrane 11 by silk screen printing of the steel mesh 18, so as to improve the accuracy of the silicate coating position and control the silicate coating thickness. The steel mesh 18 silk screen printing mode is adopted for coating operation, the consistency of operation can be improved, the problems of inaccurate manual coating position and unqualified coating thickness are avoided, and the steel mesh 18 silk screen printing mode is adopted for coating operation, so that the efficiency advantage is higher than that of manual coating. And sintering silicate on the silk-screen-printed pressure diaphragm 11 through a multi-temperature-zone vacuum tunnel furnace, and curing the strain gauge 12 on the surface of the pressure diaphragm 11. The silicate is used for solidifying the strain gauge 12 on the pressure diaphragm 11 and transmitting strain between the pressure diaphragm 11 and the strain gauge 12, when the pressure diaphragm 11 deforms under the action of pressure, the strain gauge 12 generates corresponding strain through silicate transmission, and therefore the resistance value of the strain gauge 12 changes.
Optionally, sintering the connection layer 15 on the pressure diaphragm 11 subjected to silk-screen printing through a multi-temperature-zone vacuum tunnel furnace, and curing the strain gauge 12 on the surface of the pressure diaphragm 11. Temperature control and time control in the silicate sintering and curing process are very necessary, the temperature change in the silicate sintering and curing process can be smoother by adopting the multi-temperature-zone vacuum tunnel furnace, the problem of poor sintering caused by shock cooling and shock heating can be effectively avoided, meanwhile, the multi-temperature-zone vacuum tunnel furnace also avoids workpiece oxidation, and the yield is improved.
With continued reference to fig. 1, in particular, pressure transmitter 10 further includes a housing 19, and pressure diaphragm 11 is fixedly connected to housing 19. Alternatively, the pressure diaphragm 11 is welded to the housing 19. A circuit board support 20 is arranged inside the housing 19, and the pressure membrane 11 is fixedly connected with the circuit board support 20. Optionally, the pressure membrane 11 is soldered to the circuit board mount 20. The circuit board support 20 is provided with a bonded circuit board 21, the bonded circuit board 21 is fixedly connected to the circuit board support 20, the circuit board support 20 is used for fixedly mounting the bonded circuit board 21, stress influence of the bonded circuit board 21 on the pressure diaphragm 11 is avoided, and optionally, the bonded circuit board 21 is adhered to the circuit board support 20 through a high-temperature adhesive 28. An insulating gasket 22 is disposed between the bonded circuit board 21 and the circuit board support 20, and the insulating gasket 22 is used for protecting the bonded circuit board 21 and preventing the bonded circuit board 21 and the circuit board support 20 from generating a short circuit.
Specifically, strain gage 12 is connected to bond circuit board 21 by wires 23, wires 23 being used to transfer signals between strain gage 12 and bond circuit board 21. Optionally, the conducting wire 23 is an aluminum wire, and it should be understood that the conducting wire 23 may be other wires, and is not limited to the above situation, and is not limited herein. Bonding circuit board 21 and amplification circuit board 13 are connected through first contact pin, and amplification circuit board 13 and signal conversion circuit board 14 are connected through the second contact pin, and signal conversion circuit board 14 is connected with external equipment through electrical connector 24, and electrical connector 24 plays the signal connection effect with pressure transmitter output signal and external equipment. Alternatively, the output terminal of the signal conversion circuit board 14 and the electrical connector 24 are connected by cable soldering. An electrical connector 25 is fixedly connected to the outside of the electrical connector 24, and the electrical connector 25 is connected to the housing 19. Alternatively, the electrical connector 24 is adhesively attached to the electrical connector 25, and the electrical connector 25 is soldered to the housing 19.
Specifically, bonding circuit board 21 is provided with a protective cover 26 that covers strain gauge 12 and wires 23, and protective cover 26 is fixedly connected to bonding circuit board 21. The provision of the protective cover 26 serves to protect the wires 23 and strain gauges 12 from touching, reducing the rate of damage in production turnaround. Optionally, protective cover 26 is glued to the center of bonded circuit board 21. Optionally, protective cover 26 is glued to bonded circuit board 21.
Referring to fig. 6, the present embodiment further provides a method for manufacturing a pressure transmitter, including:
step S100: the processing of the pressure diaphragm 11 specifically includes: the pressure diaphragm 11 is processed according to the design drawing, the processed pressure diaphragm 11 is placed into a vacuum furnace for heat treatment, the vacuum heat treatment avoids workpiece oxidation, the heat-treated pressure diaphragm can bear 1000-thousand pressure cycle impact, and the maximum pressure can be measured at 1000 MPa. And grinding the pressure diaphragm 11 after heat treatment to ensure that the parallelism of the pressure diaphragm 11 meets the preset requirement. Optionally, the parallelism of the pressure diaphragm after grinding is not more than 0.005 mm.
Step S200: the silicate silk-screen printing specifically comprises the following steps: fixing the pressure membrane 11 qualified in processing on the base 27, covering the prepared steel mesh 18 on the pressure membrane 11, placing the milky silicate on the steel mesh 18, uniformly scraping the silicate along the surface of the steel mesh 18 by using a scraper, then taking out the steel mesh 18, and taking down the pressure membrane 11 from the base 27, thereby completing the silk-screen printing. The steel mesh 18 needs to be designed according to the size of the strain gauge 12 and the pressure diaphragm 11, the thickness of the steel mesh 18 determines the thickness of silicate after silk-screen printing, the stability and the insulation performance of the pressure sensor are affected, and the opening position of the steel mesh 18 determines the assembly position of the strain gauge 12 (please refer to fig. 4 and 5 in combination).
Step S300: the strain gauge 12 is positioned, specifically: strain gauges 12 (see also fig. 7) are placed in the silicate covered areas of the surface of the pressure diaphragm 11.
Step S400: sintering and curing the silicate, specifically: and (3) loading the pressure diaphragms 12 subjected to silk-screen printing into a fixing clamp in batches, sequentially placing the fixing clamp into a multi-temperature-zone vacuum tunnel furnace for silicate sintering, and curing the strain gauges 12 on the surfaces of the pressure diaphragms 11 by using silicate after the silicate sintering is finished. Temperature control and time control in the silicate sintering and curing process are very necessary, the temperature change in the silicate sintering and curing process can be smoother by adopting the multi-temperature-zone vacuum tunnel furnace, the problem of poor sintering caused by shock cooling and shock heating can be effectively avoided, meanwhile, the multi-temperature-zone vacuum tunnel furnace also avoids workpiece oxidation, and the yield is improved. The multi-temperature-zone vacuum sintering furnace adopts a chain type conveying mechanism, workpieces are placed in the inlet and taken out from the outlet, the furnace temperature of each temperature zone does not need to be adjusted back and forth, and the sintering efficiency is improved.
Step S500, mounting the bonding circuit board 21, specifically: the circuit board support 20 is welded with the pressure diaphragm 11, and then the bonding circuit board 21 is fixed on the circuit board support 20 through the high-temperature adhesive 28 and is baked and cured. The bonded circuit board 21 is fixed to the circuit board support 20 by the high-temperature adhesive 28, so that the influence of the bonded circuit board 21 on the pressure diaphragm 11 is eliminated (see fig. 1 for combination).
Step S600, circuit assembly, specifically: both ends of the wire 23 are welded to the strain gauge 12 and the bonding circuit board 21, respectively, using an ultrasonic wire bonding machine, and the wire 23 and the strain gauge 12 are covered with a protective cover 26. The protective cover 26 prevents touch damage, reducing the rate of damage in production turnaround. Connecting the bonding circuit board 21 and the amplifying circuit board 13 by using a first pin, connecting the amplifying circuit board 13 and the signal conversion circuit board 14 by using a second plug-in unit, and connecting the signal conversion circuit board 14 and external equipment by using an electric connector 24;
step S700, assembling the housing 19 and the electrical connector 25, specifically: an electrical connector 25 is placed outside the electrical connector 24, and fixed by gluing, and then the electrical connector 25 is soldered to the housing 19.
Referring to fig. 8, after step S700, step S800 is further included, in which the pressure cycle impact specifically includes: the assembled pressure transmitter 10 is subjected to pressure loading unloading cyclic shock. The pressure cycle impact can eliminate the residual stress generated in the machining and workpiece assembling processes, and the loading pressure is 2 times of the full-scale pressure.
The manufacturing method of the pressure transmitter provided by the embodiment has the beneficial effects that:
according to the manufacturing method of the pressure transmitter provided by the embodiment, the manufactured pressure transmitter 10 is simple in structure, high in automation degree of the production process and high in production efficiency, batch production is realized, and the daily output of a single set of production equipment can reach 3000; the pressure transmitter 10 manufactured by the method has high pressure resistance, and the pressure diaphragm 11 after heat treatment can bear 1000 ten thousand pressure cycle impact and can measure 1000MPa pressure; the temperature drift coefficient is low, and the measurement precision is improved; the pressure diaphragm 11 adopts a micro-strain pressure sensing mode, avoids the risk of fatigue deformation of materials, prolongs the service life of the pressure diaphragm 11, and can bear 1000 ten thousand times of 1.5 times of full-scale pressure cyclic loading.
The above description is only exemplary of the present invention and should not be taken as limiting the scope of the present invention, as any modifications, equivalents, improvements and the like made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.
Claims (10)
1. A pressure transmitter (10), characterized by: the method comprises the following steps:
the pressure diaphragm (11) is made of elastic materials and has micro strain, a diaphragm pressure leading hole (111) is formed in the pressure diaphragm (11), and a plane circular diaphragm (112) is arranged at the extending end of the diaphragm pressure leading hole (111);
the strain gauge (12) is solidified on the surface of the plane circular diaphragm (112), and the resistance change of the strain gauge (12) is caused by the deformation of the plane circular diaphragm (112);
the amplifying circuit board (13) is electrically connected with the strain gauge (12), and the amplifying circuit board (13) is used for collecting resistance signals, performing temperature compensation operation on the strain gauge (12) and outputting amplified voltage signals;
and the signal conversion circuit board (14) is electrically connected with the amplification circuit board (13), and the signal conversion circuit board (14) is used for converting the input amplified voltage signal into a standard signal of the pressure transmitter and outputting the standard signal to an external device electrically connected with the signal conversion circuit board (14).
2. The pressure transmitter of claim 1, wherein: a buffer plug (16) is arranged at the opening of the diaphragm pressure guiding hole (111), and the buffer plug (16) is arranged at the opening of the diaphragm pressure guiding hole (111) and is detachably connected with the pressure diaphragm (11) through the diaphragm pressure guiding hole (111); the buffer plug (16) is provided with a buffer plug pressure guide hole (161) penetrating through the whole buffer plug (16), and the buffer plug pressure guide hole (161) is communicated with the membrane pressure guide hole (111).
3. The pressure transmitter of claim 1, wherein: the outer side wall of the pressure diaphragm (11) is provided with a stress blocking groove (113), and the stress blocking groove (113) is used for blocking the transmission of installation stress to the planar circular diaphragm (112).
4. The pressure transmitter of claim 1, wherein: the outer side wall of the pressure diaphragm (11) is provided with a process interface (17), and the process interface (17) and the pressure diaphragm (11) are of an integrated structure.
5. The pressure transmitter of claim 1, wherein: the strain gauge (12) is sintered and solidified on the surface of the plane circular diaphragm (112) through a connecting layer (15), and the connecting layer (15) is made of silicate materials.
6. The pressure transmitter of claim 5, wherein: the connecting layer (15) is coated on the pressure diaphragm (11) by adopting a steel mesh (18) silk screen printing mode, so that the accuracy of the coating position of the connecting layer (15) is improved, and the coating thickness of the connecting layer (15) is controlled.
7. The pressure transmitter of claim 6, wherein: and sintering the connection layer (15) of the pressure diaphragm (11) after silk-screen printing through a multi-temperature-zone vacuum tunnel furnace, and solidifying the strain gauge (12) on the surface of the pressure diaphragm (11).
8. The pressure transmitter of claim 1, wherein: the pressure transmitter (10) further comprises a shell (19), the pressure diaphragm (11) is fixedly connected with the shell (19), a circuit board support (20) is arranged inside the shell (19), and the pressure diaphragm (11) is fixedly connected with the circuit board support (20);
be equipped with nation decides circuit board (21) on circuit board support (20), nation decides circuit board (21) fixed connection in on circuit board support (20), just nation decides circuit board (21) with be equipped with insulating gasket (22) between circuit board support (20), insulating gasket (22) are used for protecting nation decides circuit board (21), prevent nation decides circuit board (21) with circuit board support (20) produce the short circuit.
9. The pressure transmitter of claim 8, wherein: the strain gauge (12) is connected with the bonding circuit board (21) through a lead (23), the lead (23) is used for transmitting signals between the strain gauge (12) and the bonding circuit board (21), the bonding circuit board (21) is connected with the amplifying circuit board (13) through a first contact pin, the amplifying circuit board (13) is connected with the signal conversion circuit board (14) through a second contact pin, and the signal conversion circuit board (14) is connected with external equipment through an electric connector (24);
an electrical connector (25) is fixedly connected to the outside of the electrical connector (24), and the electrical connector (25) is connected with the shell (19).
10. The pressure transmitter of claim 9, wherein: be equipped with on bonding circuit board (21) with strainometer (12) with safety cover (26) that wire (23) cover, safety cover (26) with bonding circuit board (21) fixed connection.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CN202021362799.6U CN212363529U (en) | 2020-07-10 | 2020-07-10 | Pressure transmitter |
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CN202021362799.6U CN212363529U (en) | 2020-07-10 | 2020-07-10 | Pressure transmitter |
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
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CN111811725A (en) * | 2020-07-10 | 2020-10-23 | 深圳万讯自控股份有限公司 | Pressure transmitter and manufacturing method thereof |
CN116147823A (en) * | 2022-12-21 | 2023-05-23 | 松诺盟科技有限公司 | Flat membrane type thin film core body and flat membrane type nano thin film pressure transmitter |
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN111811725A (en) * | 2020-07-10 | 2020-10-23 | 深圳万讯自控股份有限公司 | Pressure transmitter and manufacturing method thereof |
CN116147823A (en) * | 2022-12-21 | 2023-05-23 | 松诺盟科技有限公司 | Flat membrane type thin film core body and flat membrane type nano thin film pressure transmitter |
CN116147823B (en) * | 2022-12-21 | 2024-03-22 | 松诺盟科技有限公司 | Flat membrane type thin film core body and flat membrane type nano thin film pressure transmitter |
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