CN201035069Y

CN201035069Y - Four-range portable potential difference meter

Info

Publication number: CN201035069Y
Application number: CNU2007201075918U
Authority: CN
Inventors: 李顺定
Original assignee: Individual
Current assignee: Individual
Priority date: 2007-04-03
Filing date: 2007-04-03
Publication date: 2008-03-12
Anticipated expiration: 2017-04-03

Abstract

The utility model discloses a four-range portable potentiometer with three measuring disks used for direct voltage measurement. The first step inlet disk comprises a measuring disk and an auxiliary disk. The second step inlet disk comprises a measuring disk formed by ten 100 Omega ring resistance nets and an auxiliary disk formed by ten 5 Omega resistances. The third disk is a double slip lines disk, the two measuring disks are connected with measuring slip lines through conductors without switching over, which avoids the influences of variation and thermoelectric power when the potentiometer is measuring. The potentiometer has four ranges, whose minimum resolution can reach 0.1MuPsi when is multiplied by 0.01 range and also saves the replacing disk of the first and the second inlet disks.

Description

Four measuring ranges portable potentiometer

Technical field

The utility model relates to the instrument that DC voltage is measured.

Background technology

Current for the potential difference meter that three measuring disk are arranged, in the connection between three measuring disk, telophragma generally adopts switch to switch, and so just produces the variation of contact resistance, brings restriction to resolution.In order to overcome this problem, generally adopt big brush with the increase contact area, and adopt silver-carbon/carbon-copper composite material; Patent No. ZL200520101772.0 has announced that the potential difference meter that three measuring disk are arranged solves the variation new method of switch contact resistance, its first, second step disc respectively has measuring disk, replacement dish and bracket panel are formed, measuring disk is identical with resistance on the replacement dish, resistance of the every increase of measuring disk, the replacement dish just reduces same resistance, because first step disc was declined at 0 o'clock, the total resistance of circuit changed when second step disc was put different indicating value, first step disc was put at 0 o'clock, the total resistance of circuit was constant when second step disc was put different indicating value, first step disc removes for this reason measuring disk, outside the replacement dish, increased bracket panel distinguish step disc put 0 and the circuit of declining 0 two kinds of situations connect, second step disc has also increased bracket panel, has 10 resistance to insert or cut out several resistance respectively above and makes the total resistance of circuit constant.Two measuring disk connect the back and are connected two with slide wire disc and measure between terminals, brush on the step disc switch is got rid of measured outside the loop, do not exist switch to switch between the resistance on three measuring disk, also just do not produce variation; Because first, second step disc all has the replacement dish, has increased the number of plies of first, second step disc switch, thereby has increased the volume of instrument, also make switch and apparatus structure become complicated.

The utility model content

The purpose of this utility model is a kind of four measuring ranges portable potentiometer that three measuring disk are arranged of design, telophragma does not switch by switch in the connection of three measuring disk, first, second step disc cancellation replacement dish, and four range conversions are arranged, make resolution reach 0.1 μ V.

The technical solution of the utility model is taked like this: electric current from the positive pole of potential difference meter 4.5V working power through the resistance measurement network of two step discs, two slide wire disc and range transfer resistance setting resistance R to 463 Ω _NAnd the lockable adjustable resistance R of 0～0.7 Ω _P3, again to 350 Ω resistance R ₀, through 0～16 Ω adjustable resistance R _P2And 22 * 15 Ω adjustable resistance R _P1Get back to the negative pole of working power and form potential difference meter work loop; 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 R _P3, process 100K Ω current-limiting resistance R is to standard cell E again _NNegative pole is formed the potential difference meter standard loop; Be used to connect measured " U _X" two terminals, anodal terminal is through two measuring disk and after measuring the resistor network of slip, again through being connected to the double-point double-throw switch K of galvanometer G between two normally closed contacts ₂Form potential difference meter to the negative pole terminal and measure the loop; First step disc has measuring disk I, it has 0,1,2 ... 22 totally 23 gears, except that between 0,1 contact, directly connecting, connect one of 100 Ω resistance between all the other each grade contacts, other has bracket panel I ' and bracket panel I "; the brush of bracket panel I ' and bracket panel I " brush be connected bracket panel I ' and bracket panel I with lead " 0 contact isolated, all the other contacts connect with lead; The 3rd dish is two slide wire discs, two slip thickness materials are identical, resistance all is 5 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 0.5 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 10 100 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 ... welding successively, 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 other end and the 3rd dish measure 0 of slip III being connected, 0 that measures slip III is circuit node B, resistance R ₁With resistance R ₂Tie point be connected resistance R through 160 Ω resistance with the 1st contact ₂With resistance R ₃Tie point be connected resistance R through 90 Ω resistance with the 2nd contact ₃With resistance R ₄Tie point be connected resistance R through 40 Ω resistance with the 3rd contact ₄With resistance R ₅Tie point be connected resistance R through 10 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 10 Ω resistance with the 6th contact ₇With resistance R ₈Tie point be connected resistance R through 40 Ω resistance with the 7th contact ₈With resistance R ₉Tie point be connected resistance R through 90 Ω resistance with the 8th contact ₉With resistance R ₁₀Tie point be connected resistance R through 160 Ω resistance with the 9th contact ₁₀With resistance R ₉Tie point node A through 10 Ω resistance after to node C, node C is connected with the 10th contact after through 150 Ω resistance, " 0 " contact of measuring disk II is connected with Node B through 250 Ω resistance, be the resistance of 10 * 5 Ω on the bracket panel II ' of second step disc, bracket panel II ' the 10th contact and 12 Ω range transfer resistance R ₁₄An end and the positive pole of potential difference meter working power be connected in node E, 0 contact of bracket panel II ' connects bracket panel I " 0 contact, the brush of bracket panel II ' connects bracket panel I " other contact except that 0 contact, the brush of measuring disk II is through 1950 Ω resistance R ₁₂The back connects the brush and bracket panel I of bracket panel I ' " the tie point that is connected of brush; other contacts connection measuring disk I 22nd contact of bracket panel I ' except that 0 contact; measuring disk I the 0th, 1 contact is connected with node C; 0 contact of bracket panel I ' is connected with Node B after through 2200 Ω resistance, measurement slip III the 10th o'clock is through 45 Ω resistance R ₁₃Back and 10800 Ω range transfer resistance R ₁₇An end connect and node D, node D and range selector K ₁* 10 range contacts connect range transfer resistance R ₁₇The other end and 1080 Ω range transfer resistance R ₁₆An end connect range selector K ₁* 1 range contact, range transfer resistance R ₁₆The other end and 108 Ω range transfer resistance R ₁₅An end tie point through 972 Ω resistance R ₁₉Back and range selector K ₁* 0.1 range contact connects range transfer resistance R ₁₅The other end and 12 Ω range transfer resistance R ₁₄Other end tie point through 1078.92 Ω resistance R ₁₈Back and range selector K ₁* 0.01 range contact, range selector K ₁Normally closed contact connect to set up resistance R _NNoble potential one end; Potential difference meter is used to connect measured " U _X" two measure terminal, anodally be connected with measuring disk I brush, negative pole passes through double-point double-throw switch K ₂The back is connected with auxiliary slip III '.

By above technical scheme, first step disc need not the replacement dish, does not all have resistance on the two-layer bracket panel, just is contained in the switch nexine, and measuring disk I is contained in the switch skin; Second step disc need not the replacement dish, 15 ° of angles are rotated in each stepping of switch, every layer of 24 contact that distributes, deduct two grades of location, each 11 contact of the bracket panel II ' of second step disc and measuring disk II just in time are distributed in same one deck of switch, respectively account for half cycle, and resistance is contained in the switch skin, unload when resistance is overproof and load onto easily, this brings convenience for debugging and maintenance; Make potential difference meter simple in structure like this, volume-diminished has also reduced production cost; On the total circuit partly in potential difference meter internal measurement loop and work loop, there is not switch, so there is not variation influence, when three measuring disk resets of potential difference meter, the potential difference meter working current converges at the B point, what zero potential was measured is B point current potential, in measuring the loop, do not exist working current to flow through lead resistance, so this potential difference meter zero potential is very little; Two slide wire resistance thickness materials are identical, and the thermoelectrical potential equal and opposite in direction of generation, direction are opposite, so this potential difference meter thermoelectrical potential is also very little, therefore, when * 0.01 range, resolution reach 0.1 μ V, also can obtain fine repeatability during measurement,

Description of drawings

Accompanying drawing is the utility model schematic circuit.

Embodiment

Among the figure, measuring disk II has ten the 100 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 5 100 Ω resistance are in parallel with 5 100 Ω resistance between the Node B, back in parallel resistance is 250 Ω to the maximum, so corresponding point directly are connected on 5 contacts and the resistance ring, other contact of measuring disk II all will become 250 Ω with resistance value between the Node B; When measuring disk II put " 4 " or puts " 6 ", the brush of measuring disk II was to being that 4 100 Ω resistance are in parallel with 6 100 Ω resistance between the Node B, and back in parallel resistance is 240 Ω, so 4,6 contacts are connected with corresponding point on the resistance ring through 10 Ω resistance; When measuring disk II put " 3 " or puts " 7 ", the brush of measuring disk II was to being that 3 100 Ω resistance are in parallel with 7 100 Ω resistance between the Node B, and back in parallel resistance is 210 Ω, so 3,7 contacts are connected with corresponding point on the resistance ring through 40 Ω resistance; When measuring disk II put " 2 " or puts " 8 ", the brush of measuring disk II was to being that 2 100 Ω resistance are in parallel with 8 100 Ω resistance between the Node B, and back in parallel resistance is 160 Ω, so 2,8 contacts are connected with corresponding point on the resistance ring through 90 Ω resistance; When measuring disk II set or when putting " 9 ", the brush of measuring disk II is to being that 1 100 Ω resistance is in parallel with 9 100 Ω resistance between the Node B, and back in parallel resistance is 90 Ω, so 1,9 contacts are connected with corresponding point on the resistance ring through 160 Ω resistance; When measuring disk II reset, the brush of measuring disk II is to being that 250 Ω resistance connect between the Node B, and when measuring disk II puts " 10 ", the brush of measuring disk II is to being that 160 Ω resistance add 90 Ω resistance rings and connect into 250 Ω resistance between the Node B.

The first step disc reset, second step disc are put " n " (n=0,1,2,3 ... 9,10) time, the brush of bracket panel I ' is that two resistance that are both 2200 Ω are in parallel with resistance value between the Node B, is 1100 Ω therefore.

First step disc is put " n " (n=0,1,2,3 ... 22), during the second step disc reset, the brush of bracket panel I ' is that two resistance that are both 2200 Ω are in parallel with resistance value between the Node B, is 1100 Ω therefore.

When first, second step disc during not reset, the brush of bracket panel I ' and the calculating of the resistance value between the Node B except that second step disc is put " 9,10 ", 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 I ' 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)=800 * 100/1000 Ω=80 Ω

r ₁’＝R ₁×R ₁₀/(R ₁+R ₂+…+R ₁₀)＝100×100/10×100Ω＝10Ω

r ₁”＝(R ₂+R ₃+…+R ₉)×R ₁/(R ₁+R ₂+…+R ₁₀)＝800×100/1000Ω＝80Ω

Resistance value equals (2110 Ω+r between the brush of bracket panel I ' and the Node B ₁) * (2110 Ω+r ₁")/(2 * 2190) Ω+r ₁'=2190 Ω/2+10 Ω=1095 Ω+10 Ω=1105 Ω

When second step disc is put " 2 ", the calculating of resistance value between the brush of bracket panel I ' 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=70 Ω r ₂'=20 Ω r ₂"=140 Ω

Resistance value equals (2110 Ω+r between the brush of bracket panel I ' and the Node B ₂) * (1950 Ω+90 Ω+r ₂")/(2 * 2180) Ω+r ₂'=2180 Ω/2+20 Ω=1090 Ω+20 Ω=1110 Ω.

In like manner, when second step disc was put " 3 ", resistance value was 1115 Ω between the brush of bracket panel I ' and the Node B,

When second step disc was put " 4 ", resistance value was 1120 Ω between the brush of bracket panel I ' and the Node B,

When second step disc was put " 5 ", resistance value was 1125 Ω between the brush of bracket panel I ' and the Node B,

......

When second step disc was put " 9 ", resistance value was (2110/2+90) Ω=1145 Ω between the brush of bracket panel I ' and the Node B

When second step disc was put " 10 ", resistance value was (2100/2+10+90) Ω=1150 Ω between the brush of bracket panel I ' and the Node B.Because the every stepping of measuring disk II increases by 5 Ω, so the every stepping of bracket panel II ' reduces by 5 Ω, makes the total resistance of circuit constant; When the first or second step disc reset, the brush of bracket panel I ' and the resistance value between the Node B are 1100 Ω, and 10 * 5 Ω resistance of bracket panel II ' all enter circuit.

Node E arrives node D totally 1200 Ω through measuring disk, and node E is through resistance R ₁₄, resistance R ₁₅, resistance R ₁₆Also 1200 Ω, * 10, * during 1 range, resistance R ₁₇Changed the position, the circuit resistance is constant; When * 0.1 range, the resistance that circuit reduces is by sealing in 972 Ω resistance R ₁₉The holding circuit resistance is constant; When * 0.01 range, the resistance that circuit reduces is by sealing in 1078.92 Ω resistance R ₁₈The holding circuit resistance is constant;

When * 10 ranges, the 10th of bracket panel II ' is node E through Node B is 1155 Ω to the resistance between the 10th of the measurement slip III, adds 45 Ω resistance R ₁₃Arrive node D totally 1200 Ω, node E is through resistance R ₁₄, resistance R ₁₅, resistance R ₁₀, resistance R ₁₇Resistance to node D is 12000 Ω, and the electric current the during standardization of potential difference meter working current is 2.2mA, and the 2mA electric current flows through the 10th the process Node B of bracket panel II ' to node D, and 0.2mA flows through resistance R ₁₄, resistance R ₁₅, resistance R ₁₆To node D; The brush process measuring disk I of bracket panel I ' is to being equivalent to resistance r _n, r _n', r _n" intersection point Q _n(n=1,2,3 ... 8) brush of resistance value and bracket panel I ' is through 1950 Ω resistance R ₁₂To intersection point Q _nResistance value equate, so flow through measuring disk I and 1950 Ω resistance R ₁₂Electric current respectively be 1mA; When measuring disk II puts " 9 ", 1950 Ω resistance R ₁₂Add 160 Ω resistance and equate to the resistance value of node A with measuring disk I to the resistance value of node A, when measuring disk II puts " 10 ", 1950 Ω resistance R ₁₂Add 150 Ω resistance and also equate with the resistance value of measuring disk I, so flow through measuring disk I and 1950 Ω resistance R to the resistance value of node C ₁₂Electric current also respectively be 1mA.

For ten the 100 Ω end to end resistance rings of measuring disk II between 1～9 contact, resistance R during measuring disk II set ₁To be all 100 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 * 100mV=10mV; Resistance (R when measuring disk II puts " 2 " ₁+ R ₂) to be all 100 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 * 100mV=20mV; (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 * 10mV; When measuring disk II puts " 10 ", the ohmically voltage U of 90 Ω between node A and the Node B _AB=90mV adds 10 Ω resistance R ₁₁Last 10mV, 100mV altogether; When measuring disk I and measuring disk II reset, electric current is without resistance R ₁₀, U _AB=0mV; The electric current that flows through measuring disk I when not reset of measuring disk I is superimposed upon on the measuring disk II at the 100mV voltage between node C, the B, replaces the resistance between 0,1 contact, and 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＝1×100n ₁+1×n ₂/10×100+2×0.5n ₃(mV)

＝100n ₁+10n ₂+1n ₃(mV)

During * 1 range, node E through Node B to the resistance R of having connected of 1155 Ω resistance between the 10th of the measurement slip III ₁₃, resistance R ₁₇Sum is 12000 Ω and its parallel resistor R ₁₄, resistance R ₁₅, resistance R ₁₆Sum is 1200 Ω, and the 0.2mA electric current flows through the 10th the process Node B of bracket panel II ' to measuring slip III the 10th point, 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＝10n ₁+1n ₂+0.1n ₃(mV)

During * 0.1 range, node E through Node B to the resistance R of having connected of resistance between the 10th of the measurement slip III ₁₃, resistance R ₁₇And resistance R ₁₆Sum is 13080 Ω and its parallel resistor R ₁₄, resistance R ₁₅Be 120 Ω, resistance value ratio is 109 times, flows through resistance R ₁₄, resistance R ₁₅Electric current also be 109 times with the current ratio that flows through Node B, so 2.18mA current flowing resistance R ₁₄, resistance R ₁₅, the 0.02mA electric current flows through the 10th the process Node B of bracket panel II ' to measuring slip III the 10th point, 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)

During * 0.01 range, node E through Node B to the resistance R of having connected of resistance between the 10th of the measurement slip III ₁₃, resistance R ₁₇, resistance R ₁₆And resistance R ₁₅Sum is 13188 Ω and its parallel resistor R ₁₄Be 12 Ω, resistance value ratio is 1099 times, so 2.198mA current flowing resistance R ₁₄, the 0.02mA electric current flows through the 10th the process Node B of bracket panel II ' to measuring slip III the 10th point, 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 3rd dish n ₃1 μ V be 1 big scale value, every little lattice are 0.1 μ V.

The electromotive force of every series-produced standard cell disperses, and between 1.0188V～1.0196V, standardized working current is 2.2mA, therefore sets up resistance R _NGet 463 Ω, add the lockable adjustable resistance R of 0～0.7 Ω _P3, variation range that can the coverage criteria cell emf.

Potential difference meter adopts 3 groups of dry cell power supplies, and 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 350 Ω.Get adjustable resistance R _P1Be 22 * 15 Ω, adjustable resistance R _P2Be 0～16 Ω.

Normalized current is to determine like this: 2V standard signal voltage is pressed polarity and potential difference meter " U _x" two measure terminal and connect, it is identical with the standard signal magnitude of voltage that potential difference meter respectively coils total indicating value, double-point double-throw switch K ₂Throw to the left side, regulate adjustable resistance R _P1And adjustable resistance R _P2, make galvanometer G nulling; Again with double-point double-throw switch K ₂Throw to the right, regulate adjustable resistance R _P3, make galvanometer G nulling, at this moment adjustable resistance R _P3Locking; When using from now on, potential difference meter is standard according to this.

Claims

1. four measuring ranges portable potentiometer, electric current from the positive pole of potential difference meter 4.5V working power through the resistance measurement network of two step discs, two slide wire disc and range transfer resistance setting resistance R to 463 Ω _NAnd the lockable adjustable resistance R of 0～0.7 Ω _P3, again to 350 Ω resistance R ₀, through 0～16 Ω adjustable resistance R _P2And 22 * 15 Ω adjustable resistance R _P1Get back to the negative pole of working power and form potential difference meter work loop; 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 R _P3, process 100K Ω current-limiting resistance R is to standard cell E again _NNegative pole is formed the potential difference meter standard loop; Be used to connect measured " U _X" two terminals, anodal terminal is through two measuring disk and after measuring the resistor network of slip, again through being connected to the double-point double-throw switch K of galvanometer G between two normally closed contacts ₂Form potential difference meter to the negative pole terminal and measure the loop; It is characterized in that first step disc has measuring disk I, it has 0,1,2 ... 22 totally 23 gears, except that between 0,1 contact, directly connecting, connect one of 100 Ω resistance between all the other each grade contacts, other has bracket panel I ' and bracket panel I "; the brush of bracket panel I ' and bracket panel I " brush be connected bracket panel I ' and bracket panel I with lead " 0 contact isolated, all the other contacts connect with lead; The 3rd dish is two slide wire discs, two slip thickness materials are identical, resistance all is 5 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 0.5 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 10 100 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 ... welding successively, 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 other end and the 3rd dish measure 0 of slip III being connected, 0 that measures slip III is circuit node B, resistance R ₁With resistance R ₂Tie point be connected resistance R through 160 Ω resistance with the 1st contact ₂With resistance R ₃Tie point be connected resistance R through 90 Ω resistance with the 2nd contact ₃With resistance R ₄Tie point is connected resistance R through 40 Ω resistance with the 3rd contact ₄With resistance R ₅Tie point be connected resistance R through 10 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 10 Ω resistance with the 6th contact ₇With resistance R ₈Tie point be connected resistance R through 40 Ω resistance with the 7th contact ₈With resistance R ₉Tie point be connected resistance R through 90 Ω resistance with the 8th contact ₉With resistance R ₁₀Tie point be connected resistance R through 160 Ω resistance with the 9th contact ₁₀With resistance R ₉Tie point node A through 10 Ω resistance after to node C, node C is connected with the 10th contact after through 150 Ω resistance, " 0 " contact of measuring disk II is connected with Node B through 250 Ω resistance, be the resistance of 10 * 5 Ω on the bracket panel II ' of second step disc, bracket panel II ' the 10th contact and 12 Ω range transfer resistance R ₁₄An end and the positive pole of potential difference meter working power be connected in node E, 0 contact of bracket panel II ' connects bracket panel I " 0 contact, the brush of bracket panel II ' connects bracket panel I " other contact except that 0 contact, the brush of measuring disk II is through 1950 Ω resistance R ₁₂The back connects the brush and bracket panel I of bracket panel I ' " the tie point that is connected of brush; other contacts connection measuring disk I 22nd contact of bracket panel I ' except that 0 contact; measuring disk I the 0th, 1 contact is connected with node C; 0 contact of bracket panel I ' is connected with Node B after through 2200 Ω resistance, measurement slip III the 10th o'clock is through 45 Ω resistance R ₁₃Back and 10800 Ω range transfer resistance R ₁₇An end connect and node D, node D and range selector K ₁* 10 range contacts connect range transfer resistance R ₁₇The other end and 1080 Ω range transfer resistance R ₁₆An end connect range selector K ₁* 1 range contact, range transfer resistance R ₁₆The other end and 108 Ω range transfer resistance R ₁₅An end tie point through 972 Ω resistance R ₁₉Back and range selector K ₁* 0.1 range contact connects range transfer resistance R ₁₅The other end and 12 Ω range transfer resistance R ₁₄Other end tie point through 1078.92 Ω resistance R ₁₈Back and range selector K ₁* 0.01 range contact, range selector K ₁Normally closed contact connect to set up resistance R _NNoble potential one end; Potential difference meter is used to connect measured " U _X" two measure terminal, anodally be connected with measuring disk I brush, negative pole passes through double-point double-throw switch K ₂The back is connected with auxiliary slip III '.