CN201681112U - Three-range potential difference meter - Google Patents

Three-range potential difference meter Download PDF

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Publication number
CN201681112U
CN201681112U CN2009202022777U CN200920202277U CN201681112U CN 201681112 U CN201681112 U CN 201681112U CN 2009202022777 U CN2009202022777 U CN 2009202022777U CN 200920202277 U CN200920202277 U CN 200920202277U CN 201681112 U CN201681112 U CN 201681112U
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resistance
contact
node
range
tie point
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CN2009202022777U
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骆小君
骆洪亮
骆晓英
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Abstract

The utility model relates to a three-range potential difference meter, which is used for DC voltage measurement and is provided with three measurement discs. The three-range potential difference meter consists of two step discs and a double-slide wire disc, wherein the two measurement discs and measurement slide wires inside the potential difference meter are connected through conducting wires, the switch switching is not needed, the potential difference meter does not have variable difference and thermo electric potential influence during the measurement, three ranges can be obtained through changing the positions of contact range switching resistors, the minimum resolution rate reaches 0.1muV, and two auxiliary discs of the first step disc are omitted.

Description

Three measuring range potential difference meter
Technical field
The utility model relates to the instrument that DC voltage is measured.
Background technology
For the potential difference meter that three measuring disk are arranged, telophragma generally adopts switch to switch, and so just produces the variation of contact resistance, brings restriction to resolution a few days ago.In order to overcome this problem, generally adopt big brush with the increase contact area, and adopt silver-carbon/carbon-copper composite material; The patent No. 200720107585.2,200720109906.2 discloses has three three-range potential difference meters of measuring disk to solve the variation new method of switch contact resistance, its first step disc is made up of a measuring disk and two bracket panels, two measuring disk connect the back and are connected between two measurement terminals with slide wire disc, brush on the step disc switch is got rid of outside the measurement loop, do not exist switch to switch between the resistance on three measuring disk, just do not produce variation yet; Because first step disc has three layers, make switch and apparatus structure become complicated, increased the height of instrument simultaneously.
The utility model content
The purpose of this utility model is a kind of three measuring range potential difference meter of design, and telophragma does not switch by switch in the connection of three measuring disk, and two bracket panels of first step disc cancellation.
The technical solution of the utility model is taked like this:
Electric current from the positive pole of potential difference meter 1.5V working power through the resistance measurement network of two step discs between node F, the B, two slide wire disc and range transfer resistance to single-pole triple-throw (SPTT) range selector K 1Reach 441 Ω setting resistance R N and range of adjustment at the lockable adjustable resistance R of 0~0.6 Ω P2, again to the resistance R of 60 Ω 0, through the adjustable resistance R of 0~110 Ω P1Get back to the working power negative pole and form the work loop of potential difference meter; Standard cell E NAnodal through being connected to the double-point double-throw switch K of galvanometer G between two normally closed contacts 2To setting up resistance R NAnd lockable adjustable resistance, process 100K Ω current-limiting resistance R is to standard cell E again NNegative pole is formed the potential difference meter standard loop; Potential difference meter is used to connect measured " U X" two terminals, anodal terminal through the two slide wire discs of two measuring disk and after, again through being connected to the double-point double-throw switch K of galvanometer G between two normally closed contacts 2Form the potential difference meter equalizing network to the negative pole terminal; It is characterized in that first step disc has measuring disk I, it has 0,1,2 ... 22 totally 23 gears connect one of 10 Ω resistance between each gear contact; The 3rd dish is two slide wire discs, two slip thickness materials are identical, resistance all is 10 Ω, wherein one is measurement slip III, another root is auxiliary slip III ', and the index dial of two slide wire discs divides 10 big lattice, and the resistance of every big lattice correspondence is 1 Ω, every big lattice divide 10 little lattice, and the brush on two slide wire resistances is with a slice metallic brush sheet; Second step disc is made up of measuring disk II and bracket panel II ', measuring disk II has 0,1,2 ... 10 totally 11 gears have the resistance of 10 10 Ω, the 1st resistance R above 0~9 gear 1One end welds the 2nd resistance R 2One end, resistance R 2The other end welds the 3rd resistance R 3One end, resistance R 3The other end welds the 4th resistance R 4One end, resistance R 4The other end welds the 5th resistance R 5One end, resistance R 5The other end welds the 6th resistance R 6One end, resistance R 6The other end welds the 7th resistance R 7One end, resistance R 7The other end welds the 8th resistance R 8One end, resistance R 8The other end welds the 9th resistance R 9One end, the 9th resistance R 9The other end and the 10th resistance R 10An end tie point be circuit node A, the 10th resistance R 10The other end and the 1st resistance R 1The tie point of the other end be circuit node B, resistance R 1With resistance R 2Tie point be connected resistance R through 16 Ω resistance with the 1st contact 2With resistance R 3Tie point be connected resistance R through 9 Ω resistance with the 2nd contact 3With resistance R 4Tie point be connected resistance R through 4 Ω resistance with the 3rd contact 4With resistance R 5Tie point be connected resistance R through 1 Ω resistance with the 4th contact 5With resistance R 6Tie point be connected resistance R with the 5th contact 6With resistance R 7Tie point be connected resistance R through 1 Ω resistance with the 6th contact 7With resistance R 8Tie point be connected resistance R through 4 Ω resistance with the 7th contact 8With resistance R 9Tie point be connected resistance R through 9 Ω resistance with the 8th contact 9With resistance R 10Tie point be connected resistance R through 16 Ω resistance with the 9th contact 10With resistance R 9Tie point node A through 1 Ω resistance R 11The back is to node C, and node C is connected with the 10th contact after through 15 Ω resistance, and the 0th contact of measuring disk II is connected with Node B through 25 Ω resistance, is the resistance of 10 0.5 Ω on the bracket panel II ' of second step disc, and the brush of bracket panel II ' is through 205 Ω resistance R 12The back connects the brush of measuring disk II, and the brush of bracket panel II ' connects the 22nd contact of measuring disk I, the 0th contact connecting circuit node C of measuring disk I, bracket panel II ' the 10th contact and 2300 Ω resistance R 14An end tie point be node D, node D is through 5/7 Ω resistance R 15Back and 11.5 Ω range transfer resistance r 1One end is connected in parallel on node F, and node F connects the positive pole of potential difference meter working power; 2300 Ω resistance R 14The other end connect to measure the 0th contact, top of slip III, end the 10th contact of measuring slip III is through 90 Ω resistance R 13Back connecting circuit Node B; Node B and 1035 Ω range transfer resistance r 3One end is connected in parallel on single-pole triple-throw (SPTT) range selector K 1* 10 range contacts, range transfer resistance r 3The other end and 103.5 Ω range transfer resistance r 2One end is connected in parallel on single-pole triple-throw (SPTT) range selector K 1* 1 range contact, range transfer resistance r 2The other end and range transfer resistance r 1The other end connect after, through 93.15 Ω resistance r 4Connect single-pole triple-throw (SPTT) range selector K 1* 0.1 range contact, single-pole triple-throw (SPTT) range selector K 1Normally closed contact connect to set up resistance R N high potential end; Potential difference meter is used to connect measured " U X" two terminals, anodal terminal is connected with measuring disk I brush, the negative pole terminal is through double-point double-throw switch K 2The back is connected with auxiliary slip III '.
By above technical scheme, first step disc has saved two bracket panels, makes potential difference meter simple in structure, volume-diminished, also reduced production cost, in equalizing network, do not passed through switch on the circuit of three measuring disk connections simultaneously, so do not have variation and thermoelectric potential influence; The brush of first step disc and two slide wire discs switches and causes that change in resistance does not influence measurement numerical value, only influences the galvanometer damping, and compares brush with the resistance variations of whole equalizing network and switch and cause that change in resistance can ignore.
Description of drawings
Fig. 1 is the utility model schematic circuit.
In Fig. 1, the measuring disk I of 22 * 10 Ω, expression measuring disk I is made up of the resistance of 22 10 Ω; In like manner, the bracket panel II ' of 10 * 0.5 Ω, expression bracket panel II ' is made up of the resistance of 10 0.5 Ω, and resistance R in the resistance ring network of expression measuring disk II is arranged in the resistance ring network of measuring disk II " 9 * 10 Ω " 1~resistance R 9Nine resistances all are 10 Ω.
Embodiment
In Fig. 1, measuring disk II has ten the 10 end to end resistance rings of Ω between 1~9 contact, when measuring disk II puts " 5 ", the brush of measuring disk II is to being that 5 10 Ω resistance are in parallel with 5 10 Ω resistance between the Node B, back in parallel resistance is 25 Ω to the maximum, other contact of measuring disk II all will be connected to 25 Ω to the resistance between the Node B, and corresponding point directly are connected on the 5th contact of measuring disk II and the resistance ring; When measuring disk II put " 4 " or puts " 6 ", the brush of measuring disk II was to being that 4 10 Ω resistance are in parallel with 6 10 Ω resistance between the Node B, and back in parallel resistance is 24 Ω, so the 4th, 6 contacts are connected with corresponding point on the resistance ring through 1 Ω resistance; When measuring disk II put " 3 " or puts " 7 ", the brush of measuring disk II was to being that 3 10 Ω resistance are in parallel with 7 10 Ω resistance between the Node B, and back in parallel resistance is 21 Ω, so the 3rd, 7 contacts are connected with corresponding point on the resistance ring through 4 Ω resistance; When measuring disk II put " 2 " or puts " 8 ", the brush of measuring disk II was to being that 2 10 Ω resistance are in parallel with 8 10 Ω resistance between the Node B, and back in parallel resistance is 16 Ω, so the 2nd, 8 contacts are connected with corresponding point on the resistance ring through 9 Ω resistance; When measuring disk II set or when putting " 9 ", the brush of measuring disk II is to being that 1 10 Ω resistance is in parallel with 9 10 Ω resistance between the Node B, and back in parallel resistance is 9 Ω, so the 1st, 9 contacts are connected with corresponding point on the resistance ring through 16 Ω resistance; When measuring disk II reset, the 0th contact of measuring disk II is to being that 25 Ω resistance connect between the Node B, and when measuring disk II puts " 10 ", the 10th contact of measuring disk II is to being that 16 Ω resistance add 9 Ω resistance rings and connect into 25 Ω resistance between the Node B.
During the second step disc reset, the brush of bracket panel II ' is that two resistance that are both 230 Ω are in parallel with resistance value between the Node B, is 115 Ω therefore.
When the second not reset of step disc, when " 9 " reach " 10 ", the brush of bracket panel II ' and the calculating of the resistance value between the Node B all need to carry out triangle-star conversion.
During the second step disc set, the calculating of resistance value between the brush of bracket panel II ' and the Node B: establish resistance (R 2+ R 3+ ... + R 9) and resistance R 10The both sides resistance is equivalent to resistance r 1, resistance R 10With resistance R 1The both sides resistance is equivalent to resistance r 1' resistance (R 2+ R 3+ ... + R 9) and resistance R 1The both sides resistance is equivalent to resistance r 1", be equivalent to resistance r 1, r 1', r 1" intersection point is Q 1:
R then 1=(R 2+ R 3+ ... + R 9) * R 10/ (R 1+ R 2+ ... + R 10)=80 * 10/100 Ω=8 Ω
r 1’=R 1×R 10/(R 1+R 2+…+R 10+R 11)=10×10/10×10Ω=1Ω
r 1”=(R 2+R 3+…+R 9)×R 1/(R 1+R 2+…+R 10)=80×10/100Ω=8Ω
Resistance value equals (221 Ω+r between the brush of bracket panel II ' and the Node B 1) * (221 Ω+r 1")/(2 * 229) Ω+r 1'=229 Ω/2+1 Ω=114.5 Ω+1 Ω=115.5 Ω
When second step disc is put " 2 ", the calculating of resistance value between the brush of bracket panel II ' and the Node B: establish resistance (R 3+ R 4+ ... + R 9) and resistance R 10The both sides resistance is equivalent to resistance r 2, resistance R 10With resistance (R 1+ R 2) the both sides resistance is equivalent to resistance r 2' resistance (R 3+ R 4+ ... + R 9) and resistance (R 1+ R 2) the both sides resistance is equivalent to resistance r 2", be equivalent to resistance r 2, r 2', r 2" intersection point is Q 2:
R then 2=7 Ω r 2'=2 Ω r 2"=14 Ω
Resistance value equals (221 Ω+r between the brush of bracket panel II ' and the Node B 2) * (205 Ω+9 Ω+r 2")/(2 * 228) Ω+r 2'=228 Ω/2+2 Ω=114 Ω+2 Ω=116 Ω.
In like manner, when second step disc was put " 3 ", resistance value was 116.5 Ω between the brush of bracket panel II ' and the Node B,
When second step disc was put " 4 ", resistance value was 117 Ω between the brush of bracket panel II ' and the Node B,
When second step disc was put " 5 ", resistance value was 117.5 Ω between the brush of bracket panel II ' and the Node B,
……
When second step disc was put " 9 ", resistance value was (221/2+9) Ω=119.5 Ω between the brush of bracket panel II ' and the Node B, and when second step disc was put " 10 ", resistance value was (220/2+10) Ω=120 Ω between the brush of bracket panel II ' and the Node B.
Because the every stepping of measuring disk II increases by 0.5 Ω, so the every stepping of bracket panel II ' reduces by 0.5 Ω, makes the total resistance of circuit constant.
When * 10 ranges, all-in resistance is 115 Ω between node F, D, B, resistance r 1, resistance r 2With resistance r 3After the series connection 1150 Ω, resistance and resistance r between node F, D, B 1, resistance r 2With resistance r 3Therefore the resistance parallel connection of series connection back flows through that electric current is 10/11 of a voltage-measuring equipment total current between node F, D, B, flows through resistance r 1, resistance r 2With resistance r 3Electric current be 1/11 of voltage-measuring equipment working current;
When * 1 range, the resistance resistance in series r between node F, D, B 3After, with 10 times to resistance r 1With resistance r 2Resistance and resistance r 1With resistance r 2Parallel connection makes resistance r 1With resistance r 2On electric current be 10/11 of voltage-measuring equipment working current, the electric current between node F, D, B is 1/11 of a voltage-measuring equipment electric current, so electric current reduces to 1/10 on the measuring disk, the amount of making limit is reduced to 1/10.
When * 0.1 range, the resistance resistance in series r between node F, D, B 2With resistance r 3Back and resistance r 1Parallel connection, the resistance after the series connection are resistance r 1109 times, therefore flow through that total current is 1/110 of a voltage-measuring equipment working current between node F, D, B, this electric current is * electric current during 10 ranges 1/100.At * 0.1 range, resistance resistance in series r between node A, B 2With resistance r 3Back and resistance r 1Parallel connection, the resistance that reduces after the parallel connection is by series connection 93.15 Ω resistance r 4Come the holding circuit resistance constant.
Electric current during the standardization of potential difference meter working current is 2.31mA, when * 10 ranges, the 10th contact that the 2mA electric current flows through bracket panel II ' through two step discs to Node B, measuring disk II puts " n " (n=1,2,3 ... 8) time, the 22nd contact of measuring disk I is to being equivalent to resistance r n, r n', r n" intersection point Q n(n=1,2,3 ... 8) with the brush of bracket panel II ' through 205 Ω resistance R 12To intersection point Q nResistance value equates, when measuring disk II puts " 9 ", the brush of bracket panel II ' through measuring disk I to the brush of the resistance value of node A and bracket panel II ' through 205 Ω resistance R 12Resistance value to node A all equals 221 Ω, so flow through measuring disk I and 205 Ω resistance R 12Electric current respectively be 1mA, when measuring disk II puts " 10 ", the brush of bracket panel II ' through measuring disk I to the brush of the resistance value of node C and bracket panel II ' through 205 Ω resistance R 12Resistance value to node C all equals 220 Ω, so flow through measuring disk I and 205 Ω resistance R 12Electric current respectively be 1mA.
For ten the 10 Ω end to end resistance rings of measuring disk II between 1~9 contact, resistance R during measuring disk II set 1To be all 10 Ω resistance in parallel with 9 resistances, flows through resistance R 10Electric current be 1/10mA, the voltage U between node A and the Node B AB=1/10 * 10mV=1mV; Resistance (R when measuring disk II puts " 2 " 1+ R 2) to be all 10 Ω resistance in parallel with 8 resistances, flows through resistance R 10Electric current be 2/10mA, the voltage U between node A and the Node B AB=2/10 * 10mV=2mV; (n=1,2,3 when in like manner, measuring disk II puts " n " ... 9) voltage U between resistance nodes A and the Node B AB=n mV; Measuring disk II puts 10 " time, the ohmically voltage U of 9 Ω between node A and the Node B AB=9mV adds 1 Ω resistance R 11Last 1mV, 10mV altogether; Flowing through the electric current of measuring slip III is 0.1mA,
During the working current standardization, first step disc is put n 1, second step disc puts n 2, the 3rd dish puts n 3(n 3Represent big lattice indicating value) " U at this moment x" two measure that voltage is between terminal:
U x=1×10n 1+1×10+n 2/10×10-0.1×90-0.1×1×(10-n 3) (mV)
=10n 1+10+n 2-9-1+0.1n 3 (mV)
=10n 1+n 2+0.1n 3 (mV)
When * 1 range, when first step disc is put n 1, second step disc puts n 2, the 3rd dish puts n 3(n 3Represent big lattice indicating value) " U at this moment x" two measure that voltage is between terminal:
U X=n 1+0.1n 2+0.01n 3 (mv)
When * 0.1 range, when first step disc is put n 1, second step disc puts n 2, the 3rd dish puts n 3(n 3Represent big lattice indicating value) " U at this moment x" two measure that voltage is between terminal:
U X=0.1n 1+0.01n 2+0.001n 3 (mv)
The standard operation electric current is to determine like this: at * 1 range, 200mV standard signal voltage is pressed polarity and voltage measuring apparatus " U x" two measure terminal and connect, it is identical with the standard signal magnitude of voltage that voltage measuring apparatus respectively coils total indicating value, double-point double-throw switch K 2Throw to the left side, regulate adjustable resistance R P1, make galvanometer G nulling; Again with double-point double-throw switch K 2Throw to the right, regulate adjustable resistance R P2, make galvanometer G nulling, at this moment adjustable resistance R P2Locking.
The electromotive force of every series-produced standard cell disperses, and between 1.0188V~1.0196V, when * 10 ranges, standardized working current is 2.31mA, therefore sets up resistance R NGet 441 Ω, add the lockable adjustable resistance R of 0~0.6 Ω P2, variation range that can the coverage criteria cell emf.
Electromotive force was about 1.65V when dry cell was new, and to 1.4V when following, the electric current shakiness can both make the working current of potential difference meter be adjusted to standardization in order to make dry cell under new, former affection condition, for this reason resistance R with old 0Get 60 Ω.Get adjustable resistance R P1Be 0~110 Ω.

Claims (1)

1. three measuring range potential difference meter, electric current from the positive pole of potential difference meter 1.5V working power through the resistance measurement network of two step discs between node F, the B, two slide wire disc and range transfer resistance to single-pole triple-throw (SPTT) range selector K 1Reach 441 Ω setting resistance R N and range of adjustment at the lockable adjustable resistance R of 0~0.6 Ω P2, again to the resistance R of 60 Ω 0, through the adjustable resistance R of 0~110 Ω P1Get back to the working power negative pole and form the work loop of potential difference meter; Standard cell E NAnodal through being connected to the double-point double-throw switch K of galvanometer G between two normally closed contacts 2To setting up resistance R NAnd lockable adjustable resistance, process 100K Ω current-limiting resistance R is to standard cell E again NNegative pole is formed the potential difference meter standard loop; Potential difference meter is used to connect measured " U X" two terminals, anodal terminal through the two slide wire discs of two measuring disk and after, again through being connected to the double-point double-throw switch K of galvanometer G between two normally closed contacts 2Form the potential difference meter equalizing network to the negative pole terminal; It is characterized in that first step disc has measuring disk I, it has 0,1,2 ... 22 totally 23 gears connect one of 10 Ω resistance between each gear contact; The 3rd dish is two slide wire discs, two slip thickness materials are identical, resistance all is 10 Ω, wherein one is measurement slip III, another root is auxiliary slip III ', and the index dial of two slide wire discs divides 10 big lattice, and the resistance of every big lattice correspondence is 1 Ω, every big lattice divide 10 little lattice, and the brush on two slide wire resistances is with a slice metallic brush sheet; Second step disc is made up of measuring disk II and bracket panel II ', measuring disk II has 0,1,2 ... 10 totally 11 gears have the resistance of 10 10 Ω, the 1st resistance R above 0~9 gear 1One end welds the 2nd resistance R 2One end, resistance R 2The other end welds the 3rd resistance R 3One end, resistance R 3The other end welds the 4th resistance R 4One end, resistance R 4The other end welds the 5th resistance R 5One end, resistance R 5The other end welds the 6th resistance R 6One end, resistance R 6The other end welds the 7th resistance R 7One end, resistance R 7The other end welds the 8th resistance R 8One end, resistance R 8The other end welds the 9th resistance R 9One end, the 9th resistance R 9The other end and the 10th resistance R 10An end tie point be circuit node A, the 10th resistance R 10The other end and the 1st resistance R 1The tie point of the other end be circuit node B, resistance R 1With resistance R 2Tie point be connected resistance R through 16 Ω resistance with the 1st contact 2With resistance R 3Tie point be connected resistance R through 9 Ω resistance with the 2nd contact 3With resistance R 4Tie point be connected resistance R through 4 Ω resistance with the 3rd contact 4With resistance R 5Tie point be connected resistance R through 1 Ω resistance with the 4th contact 5With resistance R 6Tie point be connected resistance R with the 5th contact 6With resistance R 7Tie point be connected resistance R through 1 Ω resistance with the 6th contact 7With resistance R 8Tie point be connected resistance R through 4 Ω resistance with the 7th contact 8With resistance R 9Tie point be connected resistance R through 9 Ω resistance with the 8th contact 9With resistance R 10Tie point be connected resistance R through 16 Ω resistance with the 9th contact 10With resistance R 9Tie point node A through 1 Ω resistance R 11The back is to node C, and node C is connected with the 10th contact after through 15 Ω resistance, and the 0th contact of measuring disk II is connected with Node B through 25 Ω resistance, is the resistance of 10 0.5 Ω on the bracket panel II ' of second step disc, and the brush of bracket panel II ' is through 205 Ω resistance R 12The back connects the brush of measuring disk II, and the brush of bracket panel II ' connects the 22nd contact of measuring disk I, the 0th contact connecting circuit node C of measuring disk I, bracket panel II ' the 10th contact and 2300 Ω resistance R 14An end tie point be node D, node D is through 5/7 Ω resistance R 15Back and 11.5 Ω range transfer resistance r 1One end is connected in parallel on node F, and node F connects the positive pole of potential difference meter working power; 2300 Ω resistance R 14The other end connect to measure the 0th contact, top of slip III, end the 10th contact of measuring slip III is through 90 Ω resistance R 13Back connecting circuit Node B; Node B and 1035 Ω range transfer resistance r 3One end is connected in parallel on single-pole triple-throw (SPTT) range selector K 1* 10 range contacts, range transfer resistance r 3The other end and 103.5 Ω range transfer resistance r 2One end is connected in parallel on single-pole triple-throw (SPTT) range selector K 1* 1 range contact, range transfer resistance r 2The other end and range transfer resistance r 1The other end connect after, through 93.15 Ω resistance r 4Connect single-pole triple-throw (SPTT) range selector K 1* 0.1 range contact, single-pole triple-throw (SPTT) range selector K 1Normally closed contact connect to set up resistance R N high potential end; Potential difference meter is used to connect measured " U X" two terminals, anodal terminal is connected with measuring disk I brush, the negative pole terminal is through double-point double-throw switch K 2The back is connected with auxiliary slip III '.
CN2009202022777U 2009-12-14 2009-12-14 Three-range potential difference meter Expired - Lifetime CN201681112U (en)

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CN2009202022777U CN201681112U (en) 2009-12-14 2009-12-14 Three-range potential difference meter

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Granted publication date: 20101222

Effective date of abandoning: 20091214