阅读说明：本技术 一种宽计量范围的直流电流表 (Direct current ammeter with wide metering range ) 是由 孟娟 范建国 于 2020-06-12 设计创作，主要内容包括：本发明公开了一种宽计量范围的直流电流表,包括采样元件和采样信息处理电路,采样件用来传送采集信息的采样信息发送端连接采样信息处理电路采样信息接受端,采样信息处理电路包括计量芯片、抗混叠滤波电路和采集负载和直流充电桩电压信号的分压采样电路,抗混叠滤波电路输入端作为采样信息处理电路采样信息接受端,抗混叠滤波电路输出端连接计量芯片电流采样信号接收端,分压采样电路输出端连接计量芯片电压信号接收端。本发明提供一种宽计量范围的直流电流表。(The invention discloses a direct current ammeter with a wide metering range, which comprises a sampling element and a sampling information processing circuit, wherein a sampling information sending end of a sampling element for transmitting acquisition information is connected with a sampling information receiving end of the sampling information processing circuit, the sampling information processing circuit comprises a metering chip, an anti-aliasing filter circuit and a voltage division sampling circuit for acquiring load and direct current charging pile voltage signals, the input end of the anti-aliasing filter circuit is used as the sampling information receiving end of the sampling information processing circuit, the output end of the anti-aliasing filter circuit is connected with a current sampling signal receiving end of the metering chip, and the output end of the voltage division sampling circuit is connected with a voltage signal receiving end of the metering chip. The invention provides a direct current ammeter with a wide metering range.)

1. The utility model provides a wide measurement range's direct current ammeter, characterized by includes sampling element (1) and sampling information processing circuit (2), the sampling element sampling information sending terminal that is used for conveying the collection information connects sampling information processing circuit sampling information receiving terminal, sampling information processing circuit (2) are including measurement chip (21), anti-aliasing filter circuit (22) and the partial pressure sampling circuit (23) of electric pile voltage signal are filled to collection load and direct current, anti-aliasing filter circuit input is as sampling information processing circuit sampling information receiving terminal, measurement chip electric current sampling signal receiving terminal is connected to anti-aliasing filter circuit output, partial pressure sampling circuit output is connected measurement chip voltage signal receiving terminal.

2. The direct current meter with wide metering range of claim 1, characterized by further comprising a power supply circuit (3), wherein the power supply circuit comprises a direct current power supply (31), a DC/DC circuit (32) and an isolated DC/DC circuit (33), the output end of the direct current power supply is connected with the input end of the DC/DC circuit, the output end of the DC/DC circuit is connected with the input end of the isolated DC/DC circuit, and the output end of the isolated DC/DC circuit is connected with the power supply end of the metering chip (21); the sampling information processing circuit (2) further comprises an RC filter circuit (24), the output end of the voltage division sampling circuit (23) is connected with the input end of the RC filter circuit, and the output end of the RC filter circuit is connected with the voltage signal receiving end of the metering chip (21).

3. A wide metering range dc current meter as claimed in claim 1, characterized in that the sampling element (1) comprises a diverter (11) on which the sampler is arranged, a sampler (12) on which the heat sink is arranged, and a heat sink (13) on which a number of recesses (111) are arranged, which recesses are adapted to the recesses and into which recesses projections can be inserted.

4. A method for operating a wide-metering-range dc ammeter using a wide-metering-range dc ammeter as claimed in any one of claims 1 to 3, the method comprising the steps of:

s1: calibrating data of a large-current direct-current ammeter;

s2: detecting a calibration result, judging the calibration result, and starting a corresponding repair mechanism according to the judgment result;

s3: setting a range limit threshold, and removing the ammeter with the calculation error larger than the range limit threshold from the ammeter used for metering and sampling.

5. The method of claim 1, wherein the step S1 comprises the steps of:

s11: calibrating a charging line signal;

s12: calibrating the charging loop current;

s13: carrying out current and voltage gain calibration; the voltage and current calibration formula is as follows:

in the formula: vgain is a voltage and current gain coefficient, m is a platform body standard value, Vgain 'is an old voltage and current gain coefficient, and V' is a voltage value measured by an ammeter;

the calibration process is as follows: loading a voltage f1 of V + and a voltage V + 'and a current t1 on a calibration device, inputting actual voltage and current values to calibration software, and updating a voltage gain coefficient Vgain of a V + channel and a V +' channel and a current gain coefficient Igain of an I channel in a table;

s14: performing active power gain calibration; the active power calibration formula is as follows:

in the formula: pgain is a power gain coefficient, m1 is a platform standard value, Pgain 'is an old power gain coefficient, and P' is a power value measured by an ammeter;

the active power calibration method comprises the following steps: loading a voltage f2 of V + and V +' and a current t2 on a calibration device, inputting an actual power value p1 of the table body to calibration software, inputting a standard value into a table, and updating a power gain coefficient Pgain in the table;

s15: performing compensation calibration on the small signal;

s16: calibrating a load cathode channel end V- ', performing direct current compensation calibration on the load cathode channel end V- ', grounding the load cathode channel end V- ', wherein a direct current instantaneous value is a compensation value, and storing the compensation value; the voltage and current calibration formula is as follows:

vgain1 is the voltage gain factor, m0 is the standard table body standard value, Vgain1 ' is the old voltage V- ' gain factor, and V ' is the voltage value measured by the electric meter.

6. The method of claim 1, wherein the step S11 comprises the steps of:

s111: performing direct current compensation calibration on the charging pile signal channel end V +, grounding the charging pile signal channel end V +, taking a direct current instantaneous value as a compensation value, and storing the compensation value;

s112: carrying out direct current compensation calibration on the load anode channel end V + ', inputting the load anode channel end V +', grounding, and storing a compensation value, wherein a direct current instantaneous value is the compensation value;

s113: performing effective value secondary noise compensation on a charging pile signal channel end V + channel, grounding the charging pile signal channel end V +, taking the square accumulated data as a compensation value, and storing the compensation value;

s114: and carrying out effective value secondary noise compensation on the load anode channel end V + 'channel, inputting the load anode channel end V +' to the ground, taking the square accumulated data as a compensation value, and storing the compensation value.

7. The method of claim 1, wherein the step S12 comprises the steps of:

s121: performing direct current compensation calibration on the loop current signal I, inputting the loop current signal I to the ground, taking a direct current instantaneous value as a compensation value, and storing the compensation value;

s122: and performing effective value secondary noise compensation on the loop current signal I, inputting the loop current signal I to the ground, taking the square accumulated data as a compensation value, and storing the compensation value.

8. The method of claim 1, wherein the step S15 comprises the steps of:

s151: and (3) current small signal compensation calibration: the current small signal calibration formula is as follows: ioffset ═ m 2-I';

ioffset is a small current compensation coefficient, m2 is a standard platform body standard value, and I' is a current value measured by the ammeter;

the current small signal calibration method comprises the following steps: loading a reference voltage V +, V +', Un ═ f3 and a reference current 5% Ib ═ t3 on a calibration device, inputting the actual current value of the standard table body to calibration software, inputting the standard value to a table, and updating a small current compensation coefficient Ioffset in the table;

s152: and (3) voltage small signal compensation calibration: the voltage small signal calibration formula is as follows: voffset ═ m 2-V';

voffset is a small voltage compensation coefficient, m2 is a standard value of the standard platform body, and I' is a voltage value measured by the ammeter;

the voltage small signal calibration method comprises the following steps: loading a reference voltage V +, V +', Un ═ f3 and a reference current 5% Ib ═ t3 on a calibration device, inputting an actual voltage value of a standard table body to calibration software, inputting the standard value to a table, and updating a small voltage compensation coefficient Voffset in the table;

s153: and (3) power small signal compensation calibration: the power small signal calibration formula is as follows: poffset ═ m3-P ";

poffset is a power small signal compensation coefficient, m3 is a standard platform body standard value, and P' is a power value measured by an ammeter;

the power small signal calibration method comprises the following steps: loading a reference voltage V +, V +', Un ═ f4 and a reference current 5% Ib ═ t4 on a calibration device, inputting the actual current value of the standard table body to calibration software, inputting the standard value to a table, and updating a small current compensation coefficient Poffset in the table.

9. The method of claim 1, wherein the step S2 comprises the steps of:

s21: checking the meter calibrating parameters by self, detecting whether the current meter calibrating parameter is checked correctly, if so, jumping to the step S24, otherwise, jumping to the step S22;

s22: judging whether the backup checksum is correct or not, if so, jumping to the step S24, otherwise, jumping to the step S23;

s23: taking the default calibration parameters of the program memory to participate in the metering and starting the next step;

s24: and copying the correct corner mark parameters into a program memory to participate in metering.

10. The method of claim 1, wherein the step S3 is a specific process of: and setting an error threshold value, calculating the calculation error in the table, if the calculation error in the table is smaller than the error threshold value, normally working, otherwise, not metering the table, and rejecting the table.

Technical Field

The invention relates to the technical field of meters, in particular to a direct current ammeter with a wide metering range.

Background

The range of the current direct current ammeter is subjected to the problem that small signals are difficult to measure and calculate, so that the small range cannot be accurately measured, and the large range is difficult to promote due to the problem that the direct current ammeter dissipates heat, however, along with popularization of electric automobiles, direct current charging piles can be more and more, so that how to accurately measure the power consumption is an important technical problem, and the direct current ammeter with a wide measuring range is required to appear.

The invention discloses a Chinese patent publication No. CN110763910A, published 2020, 02/07, entitled digital display DC meter and a current sampling circuit thereof, wherein the current sampling circuit comprises a reference signal module, a circuit protection module, a Hall current acquisition circuit, a voltage division filtering module, an emitter follower circuit and a current acquisition filtering module which are sequentially connected in series; the input end of the Hall current acquisition circuit is connected with the detected current, the input end of the reference signal module is connected with the Hall current acquisition circuit, the circuit protection module is connected with the Hall current acquisition circuit and the common end of the voltage division filtering module, and the output end of the current acquisition filtering module and the output end of the reference signal module are both connected with the processor of the digital display DC meter. The direct current meter calibration mode of the application is inaccurate, so that the range of the direct current meter is inaccurate, and the range of small range cannot be expanded.

Disclosure of Invention

The invention provides a direct current meter with a wide metering range, aiming at overcoming the problem that the metering range of the direct current meter in the prior art is not large enough.

In order to achieve the purpose, the invention adopts the following technical scheme:

the technical scheme adopted by the invention for solving the technical problems is as follows:

the utility model provides a wide measurement range's direct current ammeter, including sampling component and sampling information processing circuit, the sampling component sampling information sending terminal that is used for conveying the information of gathering connects sampling information processing circuit sampling information receiving terminal, sampling information processing circuit includes the measurement chip, anti-aliasing filter circuit and the partial pressure sampling circuit who gathers load and direct current and fill electric pile voltage signal, anti-aliasing filter circuit input is as sampling information processing circuit sampling information receiving terminal, measurement chip current sampling signal receiving terminal is connected to anti-aliasing filter circuit output, partial pressure sampling circuit output is connected measurement chip voltage signal receiving terminal.

Preferably, the ammeter further comprises a power supply circuit, the power supply circuit comprises a direct-current power supply, a DC/DC circuit and an isolation DC/DC circuit, the output end of the direct-current power supply is connected with the input end of the DC/DC circuit, the output end of the DC/DC circuit is connected with the input end of the isolation DC/DC circuit, and the output end of the isolation DC/DC circuit is connected with the power end of the metering chip; the sampling information processing circuit further comprises an RC filter circuit, the output end of the partial pressure sampling circuit is connected with the input end of the RC filter circuit, and the output end of the RC filter circuit is connected with the voltage signal receiving end of the metering chip.

Preferably, the sampling element comprises a shunt, a sampler and a cooling fin, the sampler is arranged on the shunt, the cooling fin is arranged on the shunt, a plurality of recesses are formed in the shunt, and protrusions which are matched with the recesses and can be inserted into the recesses are formed in the cooling fin. The shunt is a device for extracting a current signal from a direct current charging loop, and has the characteristic of high resistance, because when a large current passes through the shunt, the high resistance can generate a large amount of heat, the shunt needs to be cooled, the heat generated by the shunt can not influence the work of a direct current meter, the radiating fin is provided with a protrusion which is matched with the recess and can be inserted into the recess, the contact area of the radiating fin and the shunt can be increased, and the heat is better radiated by the shunt.

A method for operating a direct current ammeter with a wide metering range, which adopts the direct current ammeter with the wide metering range, comprises the following steps:

s1: calibrating data of a large-current direct-current ammeter;

s2: detecting a calibration result, judging the calibration result, and starting a corresponding repair mechanism according to the judgment result;

s3: setting a range limit threshold, and removing the ammeter with the calculation error larger than the range limit threshold from the ammeter used for metering and sampling. Because the manganese copper (shunt) resistance value of the DC meter has certain deviation in batch production, the DC meter can be calibrated in a full-range manner in batch production, so that various parameters are in a standard range; for example, the direct current meter is a standard of a primary meter, after calibration, the error of the voltage, the current and the power should be controlled within 1%, the internal control requirement of the factory is controlled within 0.4%, and the internal control standards of different calibration points are different.

Different from other measurement chip SOC calibration methods, the parameters calibrated by the measurement chip SOC calibration methods directly act on an internal register of a chip, and if the value in the register of the chip is abnormal, the value cannot be recovered, so that the field measurement error is abnormal. The meter calibration parameters are stored in the nonvolatile memory, and the method has the advantages that three sets of meter calibration parameters are made, one set is the current meter calibration parameter, the other set is the backup meter calibration parameter, and the other set is the default meter calibration parameter. When the current meter calibration parameters are abnormal, the backup meter calibration parameters are used, and when the backup is abnormal, the default meter calibration parameters are used.

Preferably, the step S1 includes the steps of:

yes step S1 includes the following steps:

s11: calibrating a charging line signal;

s12: calibrating the charging loop current;

s13: carrying out current and voltage gain calibration; the voltage and current calibration formula is as follows:

in the formula: vgain is a voltage and current gain coefficient, m is a platform body standard value, Vgain 'is an old voltage and current gain coefficient, and V' is a voltage value measured by an ammeter;

the calibration process is as follows: and loading the voltage f1 of V + and V + 'and the current t1 on the calibration device, inputting the actual voltage and current values to calibration software, and updating the voltage gain coefficients Vgain of the V + channel and the V +' channel and the current gain coefficient Igain of the I channel in a table.

S14: performing active power gain calibration; the active power calibration formula is as follows:

in the formula: pgain is a power gain coefficient, m1 is a platform standard value, Pgain 'is an old power gain coefficient, and P' is a power value measured by an ammeter;

the active power calibration method comprises the following steps: and loading a voltage f2 of V + and V +' on the calibration device, inputting a current t2 to the calibration software, inputting the actual power value p1 of the table body, inputting a standard value into a table, and updating a power gain coefficient Pgain in the table.

S15: performing compensation calibration on the small signal;

s16: calibrating a load cathode channel end V- ', performing direct current compensation calibration on the load cathode channel end V- ', grounding the load cathode channel end V- ', wherein a direct current instantaneous value is a compensation value, and storing the compensation value; the voltage and current calibration formula is as follows:

vgain1 is the voltage gain factor, m0 is the standard table body standard value, Vgain1 ' is the old voltage V- ' gain factor, and V ' is the voltage value measured by the electric meter. The power is calibrated and integrated to calculate the energy value.

Preferably, the step S11 includes the steps of:

s111: performing direct current compensation calibration on the charging pile signal channel end V +, grounding the charging pile signal channel end V +, taking a direct current instantaneous value as a compensation value, and storing the compensation value;

s112: carrying out direct current compensation calibration on the load anode channel end V + ', inputting the load anode channel end V +', grounding, and storing a compensation value, wherein a direct current instantaneous value is the compensation value;

s113: performing effective value secondary noise compensation on a charging pile signal channel end V + channel, grounding the charging pile signal channel end V +, taking the square accumulated data as a compensation value, and storing the compensation value;

s114: and carrying out effective value secondary noise compensation on the load anode channel end V + 'channel, inputting the load anode channel end V +' to the ground, taking the square accumulated data as a compensation value, and storing the compensation value. The chip can be configured with a direct current metering mode, and noise can be compensated through a direct current compensation function in the direct current metering mode; in order to obtain higher precision of the effective value under a small signal, secondary compensation can be carried out on the effective value, and effective value noise is compensated.

Preferably, the step S12 includes the steps of:

s121: performing direct current compensation calibration on the loop current signal I, inputting the loop current signal I to the ground, taking a direct current instantaneous value as a compensation value, and storing the compensation value;

s122: and performing effective value secondary noise compensation on the loop current signal I, inputting the loop current signal I to the ground, taking the square accumulated data as a compensation value, and storing the compensation value. The chip can be configured with a direct current metering mode, and noise can be compensated through a direct current compensation function in the direct current metering mode; in order to obtain higher precision of the effective value under a small signal, secondary compensation can be carried out on the effective value, and effective value noise is compensated.

Preferably, the step S15 includes the steps of:

s151: and (3) current small signal compensation calibration: the current small signal calibration formula is as follows: ioffset is m 2-I'.

Ioffset is a small current compensation coefficient, m2 is a standard platform body standard value, and I' is a current value measured by the ammeter;

the current small signal calibration method comprises the following steps: loading a reference voltage V +, V +', Un ═ f3 and a reference current 5% Ib ═ t3 on a calibration device, inputting the actual current value of the standard table body to calibration software, inputting the standard value to a table, and updating a small current compensation coefficient Ioffset in the table;

s152: and (3) voltage small signal compensation calibration: the voltage small signal calibration formula is as follows: voffset equals m 2-V'.

Voffset is a small voltage compensation coefficient, m2 is a standard value of the standard platform body, and I' is a voltage value measured by the ammeter;

the voltage small signal calibration method comprises the following steps: loading a reference voltage V +, V +', Un ═ f3 and a reference current 5% Ib ═ t3 on a calibration device, inputting an actual voltage value of a standard table body to calibration software, inputting the standard value to a table, and updating a small voltage compensation coefficient Voffset in the table;

s153: and (3) power small signal compensation calibration: the power small signal calibration formula is as follows: poffset ═ m3-P ";

poffset is a power small signal compensation coefficient, m3 is a standard platform body standard value, and P' is a power value measured by an ammeter;

the power small signal calibration method comprises the following steps: loading a reference voltage V +, V +', Un ═ f4 and a reference current 5% Ib ═ t4 on a calibration device, inputting the actual current value of the standard table body to calibration software, inputting the standard value to a table, and updating a small current compensation coefficient Poffset in the table. After the rated current is calibrated, the error of the small current needs to be seen, and the error of the small current is usually large at this time; in order to ensure that the small current measurement is more accurate, current small signal compensation calibration needs to be added; the calibration parameters are numerous and the related range is wide. And calibrating noise bias aiming at three paths of voltage and one path of current channel. The compensation is carried out on small current, small voltage and small power, so that the small metering range can be enlarged.

Preferably, the step S2 includes the steps of:

s21: checking the meter calibrating parameters by self, detecting whether the current meter calibrating parameter is checked correctly, if so, jumping to the step S24, otherwise, jumping to the step S22;

s22: judging whether the backup checksum is correct or not, if so, jumping to the step S24, otherwise, jumping to the step S23;

s23: taking the default calibration parameters of the program memory to participate in the metering and starting the next step;

s24: and copying the correct corner mark parameters into a program memory to participate in metering. The calibrated parameters can be correctly used in the memory, and a set of meter calibrating parameter checking mechanism is designed in the program, so that the meter calibrating parameters are used to form a closed loop, and the reliability of accurate metering is improved.

Preferably, the step S3 includes the following specific steps: and setting an error threshold value, calculating the calculation error in the table, if the calculation error in the table is smaller than the error threshold value, normally working, otherwise, not metering the table, and rejecting the table. In the above, the resistance values of the manganin are different to a certain extent in batch, and if the difference is extremely large, the manganin is not required to be used for metering and sampling and is eliminated before leaving the factory. When the three parameters of the voltage, the current and the power are calibrated, the calibration range is limited in the program. For example, a calibrated table uses default calibration parameters, which are described above to control the error to within 5%. Assuming that the table body is loaded with 1000V, the voltage value measured by the ammeter before being calibrated is 1100V, (1100-1000/1000 is 10%), the calibration software is used for calibrating and inputting 1000V at this time, the calculation error in the table is larger than 5% (the error range in the table is limited by 5%), the calibration is not successful, and the upper computer software can prompt failure. In the process of checking the meter, a method for limiting the range of the meter checking is added, so that the large errors caused by errors on poor manganin or hardware circuits can be effectively eliminated, the qualification rate of products is improved, and the efficiency of problem troubleshooting is improved. In the process of checking the meter, a method for limiting the range of the meter checking is added, so that the large errors caused by errors on poor manganin or hardware circuits can be effectively eliminated, the qualification rate of products is improved, and the efficiency of problem troubleshooting is improved.

Therefore, the invention has the following beneficial effects: (1) different from other measurement chip SOC calibration methods, the parameters calibrated by the measurement chip SOC calibration methods directly act on an internal register of a chip, and if the value in the register of the chip is abnormal, the value cannot be recovered, so that the field measurement error is abnormal. The meter calibration parameters are stored in the nonvolatile memory, and the method has the advantages that three sets of meter calibration parameters are made, one set is the current meter calibration parameter, the other set is the backup meter calibration parameter, and the other set is the default meter calibration parameter. When the current meter calibrating parameter is abnormal, the backup meter calibrating parameter is used, and when the backup is abnormal, the default meter calibrating parameter is used;

(2) after the rated current is calibrated, the error of the small current needs to be seen, and the error of the small current is usually large at this time; in order to ensure that the small current measurement is more accurate, current small signal compensation calibration needs to be added; the calibration parameters are numerous and the related range is wide. And calibrating noise bias aiming at three paths of voltage and one path of current channel. Small current, small voltage and small power are compensated, so that the metering range is expanded;

(3) in the process of checking the meter, a method for limiting the range of the meter checking is added, so that the large errors caused by the errors on poor manganin or hardware circuits can be effectively eliminated, the qualification rate of products is improved, and the efficiency of problem troubleshooting is improved;

(3) the shunt is a device for extracting a current signal from a direct current charging loop, and has the characteristic of high resistance, because when a large current passes through the shunt, the high resistance can generate a large amount of heat, the shunt needs to be cooled, the heat generated by the shunt can not influence the work of a direct current meter, the radiating fin is provided with a protrusion which is matched with the recess and can be inserted into the recess, the contact area of the radiating fin and the shunt can be increased, and the heat is better radiated by the shunt.

Drawings

FIG. 1 is a block diagram of an architecture of the present invention

FIG. 2 is a schematic diagram of a structure of the present invention

FIG. 3 is a schematic view of a through hole structure of the present invention

FIG. 4 is a schematic view of a through slot structure of the present invention

In the figure: 1. the circuit comprises a sampling element, 11 parts of a current divider, 111 parts of a recess, 1111 parts of a through hole, 1112 parts of a through groove, 12 parts of a sampler, 13 parts of a heat radiating fin, 2 parts of a sampling information processing circuit, 21 parts of a metering chip, 22 parts of an anti-aliasing filter circuit, 23 parts of an RC filter circuit, 24 parts of an anti-aliasing filter circuit, 3 parts of a power supply circuit, 31 parts of a direct current power supply, 32 parts of a DC/DC circuit and 33 parts of an isolation DC/DC circuit.

Detailed Description

The invention is further described with reference to the following detailed description and accompanying drawings.