CN203950137U - Many gears resistance output unit, detection system - Google Patents

Abstract

Many gears resistance output unit, comprising: the first control loop, the second control loop, very first time relay, the first resistance and the second resistance; Described the first control loop comprises switch and the first electromagnetic type relay, described the first electromagnetic type relay comprises coil, the first normally opened contact, the second normally opened contact and the 3rd normally opened contact, described the second control loop comprises the second electromagnetic type relay and second time relay, described the second electromagnetic type relay comprises coil and normally opened contact, and described second time relay comprises coil, the first normally opened contact, the second normally opened contact and normally closed contact.By the first control loop, control output and the disconnection of the first resistance, by the second control loop, control output and the disconnection of the second resistance.The utility model also provides another kind of many gears resistance output unit and detection system.Device by the utility model scheme has been simplified design, has reduced cost.System by the utility model scheme has improved detection efficiency.

Description

Many gears resistance output unit, detection system

Technical field

The utility model relates to automatic adjustment technology field, particularly relates to a kind of many gears resistance output unit, detection system.

Background technology

In the fields such as industrial electric, conventionally to use resistance.There is at present resistance miscellaneous, such as fixed resistance value resistance, adjustable resistance etc.Can use resistance box that measuring resistance is provided.But adopt resistance box to export different resistance, need manual shift, troublesome poeration, efficiency is low.

In conventional art, also adopt resistance self-checking device.This device comprises the electric resistance array being contained on printed-wiring board (PWB), relay array, power drive array, the edge connector being connected with external digital amount signal and lead-in wire is also housed on printed-wiring board (PWB) and forms.Digital quantity signal connects the input of power drive array, by conducting or the cut-off of high level or the low level control power drive device of digital quantity signal.The output of power drive array connects the input of relay array, a relay in each power drive device correspondence and relay array, the input control coil of the output of power drive device and relay is connected in series, by the conducting of power drive device or cut-off control the corresponding relay coil connecting electric or dead electricity, realize the public electric shock of this relay and the connection of normally opened contact or with the connection of normally closed contact.A resistance in the corresponding electric resistance array of relay array repeat circuit, two end points by resistance connect relay normally open contact corresponding to it, normally closed contact, form a resistance adjustment unit, previous resistance adjustment unit repeat circuit common connects an end points of resistance in next resistance adjustment unit, is connected in series and forms a resistance adjustment circuit between resistance adjustment unit.

Adopt the self-checking device in conventional art, although can realize the automatic adjusting of resistance, need to be by conducting or the cut-off of high level or the low level control power drive device of digital quantity signal, and then pilot relay, realize the adjusting to resistance.Design is complicated, and cost is high.

At present, in electric substation automation system, to power transformer oil surface temperature, collection is mainly carried out data acquisition by temperature transmitter, and it is inner that this temperature transmitter is arranged on main transformer observing and controlling screen.The secondary acquisition loop of main transformer temperature data mainly comprises: in temperature sense part, resistance importation, transmitter, transmitter direct current output, electric substation automation system, measure and control device, supervisory control of substation backstage show the end demonstration with electric substation automation system main website.

In the physical device debugging course of receiving, because of main-transformer charging operation not, main-transformer interior oil temperature and outdoor temperature are suitable, are difficult to change main transformer oil temperature temperature.Therefore, when main-transformer is not charged, cannot check temperature transmitter, also cannot simulate various different temperatures data measure and control device in electric substation automation system is carried out to data check simultaneously.

In addition, in temperature acquisition loop, temperature transmitter precision is inaccurate, secondary circuit wiring loosening, temperature transmitter duty is abnormal, measure and control device gathers plug-in unit fault or definite value that the improper main-transformer temperature data that all can cause that in electric substation automation system, measure and control device gathers is set is inaccurate in electric substation automation system.Now, common way is to need power transformation primary equipment maintainer by debugging each temperature parameter, equipment component of transformer to be checked, and power transformation secondary personnel need check secondary device in transformer station and loop feature thereof by debugging each temperature parameter, need many teams and groups, multidisciplinary maintainer to carry out inspection work in transformer station, and exist and check that the working time is longer, the features such as unintelligible, the difficult judgement in trouble spot, the security, the reliability that have a strong impact on equipment operation, increased operation maintenance technician and checked workload.

Utility model content

Based on this, be necessary the problem complicated for the design of resistance robotization output unit, cost is high, a kind of many gears resistance output unit is provided.

Many gears resistance output unit, comprising: the first control loop, the second control loop, very first time relay, the first resistance and the second resistance;

Described the first control loop comprises switch and the first electromagnetic type relay, described the first electromagnetic type relay comprises coil, the first normally opened contact, the second normally opened contact and the 3rd normally opened contact, described the second control loop comprises the second electromagnetic type relay and second time relay, described the second electromagnetic type relay comprises coil and normally opened contact, and described second time relay comprises coil, the first normally opened contact, the second normally opened contact and normally closed contact;

The coil of described power input, described switch, described the first electromagnetic type relay, the normally closed contact of described second time relay are connected successively with power output end, and the first normally opened contact of described the first electromagnetic relay is connected with switch in parallel;

The second normally opened contact of described power input, the first electromagnetic type relay, the coil of the second electromagnetic type relay, the coil of second time relay, the normally closed contact of very first time relay are connected successively with power output end, and the second normally opened contact of the normally opened contact of described the second electromagnetic type relay and described the first electromagnetic type relay is connected in parallel;

The first normally opened contact of described power input, described second time relay, the coil of described very first time relay are connected successively with power output end;

The 3rd normally opened contact of resistance output terminal anode, the first electromagnetic type relay, the first resistance and resistance output terminal negative terminal are connected successively, and the second normally opened contact of described resistance output terminal anode, second time relay, the second resistance and resistance output terminal negative terminal are connected successively.

Above-mentioned many gears resistance output unit, is connected with power output end successively by the coil of power input, switch, the first electromagnetic type relay, the normally closed contact of second time relay, and the first normally opened contact of the first electromagnetic relay is connected with switch in parallel; By the second normally opened contact of power input, the first electromagnetic type relay, the coil of the coil of the second electromagnetic type relay, second time relay, the normally closed contact of very first time relay is connected successively with power output end, the second normally opened contact of the normally opened contact of the second electromagnetic type relay and the first electromagnetic type relay is connected in parallel.The 3rd normally opened contact, the first resistance and resistance output terminal negative terminal by resistance output terminal anode, the first electromagnetic type relay are connected successively, and the second normally opened contact of resistance output terminal anode, second time relay, the second resistance and resistance output terminal negative terminal are connected successively.Realize the first electromagnetic type relay and control being connected and disconnection of the first resistance and resistance output terminal anode and output terminal, control the conducting of the second control loop.Second time relay is controlled the disconnection of the first control loop, and control being connected and disconnection of the second resistance and resistance output terminal anode and output terminal, thereby realize the output that the first control loop is controlled the first resistance, the second control loop is controlled the output of the second resistance, can realize two gear resistance and automatically export.Simplicity of design, cost is low.

Based on this, be necessary the problem complicated for the design of resistance robotization regulating device, cost is high, a kind of many gears resistance output unit is provided.

A kind of many gears resistance output unit, comprise: the first control loop, the second control loop, the 3rd control loop, very first time relay, the first resistance, the second resistance and the 1st are to N resistance, described the 3rd control loop comprises N sub-control loop, and each sub-control loop is connected in parallel;

Described the first control loop comprises switch and the first electromagnetic type relay, described the first electromagnetic type relay comprises coil, the first normally opened contact, the second normally opened contact and the 3rd normally opened contact, described the second control loop comprises the second electromagnetic type relay and second time relay, described the second electromagnetic type relay comprises coil and normally opened contact, and described second time relay comprises coil, the first normally opened contact, the second normally opened contact and normally closed contact; I sub-control loop comprises i electromagnetic type relay and the i time relay, described i electromagnetic type relay comprises coil and normally opened contact, the described i time relay comprises coil, the first normally opened contact, the second normally opened contact and normally closed contact, wherein, and i ∈ N;

The coil of described power input, described switch, described the first electromagnetic type relay, the normally closed contact of described second time relay are connected successively with power output end, and the first normally opened contact of described the first electromagnetic relay is connected with switch in parallel;

The second normally opened contact of described power input, the first electromagnetic type relay, the coil of the second electromagnetic type relay, the coil of second time relay, the normally closed contact of the 1st time relay are connected successively with power output end, and the second normally opened contact of the normally opened contact of described the second electromagnetic type relay and described the first electromagnetic type relay is connected in parallel;

Described power input, the first normally opened contact of the i-1 time relay, the coil of i electromagnetic type relay, the coil of the i time relay, the normally closed contact of the i+1 time relay is connected successively with power output end, the normally opened contact of described i electromagnetic type relay and the first normally opened contact of the described i-1 time relay are connected in parallel, wherein, described i=1, the first normally opened contact of the described i-1 time relay is the first normally opened contact of described second time relay, described i=N, the normally closed contact of the described i+1 time relay is the normally closed contact of very first time relay,

The first normally opened contact of described power input, the described N time relay, the coil of described very first time relay are connected successively with power output end;

The 3rd normally opened contact of resistance output terminal anode, the first electromagnetic type relay, the first resistance and resistance output terminal negative terminal are connected successively, the second normally opened contact of described resistance output terminal anode, second time relay, the second resistance and resistance output terminal negative terminal are connected successively, and the second normally opened contact, i resistance and the resistance output terminal negative terminal of described resistance output terminal anode, the i time relay are connected successively.

Above-mentioned many gears resistance output unit, while realizing the first control loop conducting by above-mentioned design, the first control loop is controlled the first resistance conducting, output the first resistance, the first control loop is controlled the second control loop conducting; During the second control loop conducting, the second control loop is controlled the first control loop and is disconnected at Preset Time, control the second resistance in Preset Time conducting, export the second resistance, and control the 1st sub-control loop in Preset Time conducting, after the first control loop disconnects, the first control loop is controlled the first resistance and is disconnected; During the sub-control loop conducting of i, the sub-control loop of i is controlled i-1 control loop and is disconnected at Preset Time, control i resistance in Preset Time conducting, export i resistance, and control i+1 control loop in Preset Time conducting, after i-1 control loop disconnects, i-1 control loop is controlled i-1 resistance and is disconnected.During very first time relay conducting, the sub-control loop of very first time Control N disconnects at Preset Time, and after the sub-control loop of N disconnects, the sub-control loop of N is controlled N resistance and disconnected.Thereby can realize the automatic output of N+2 resistance, realize the automatic replacing of N+2 gear.Simplicity of design, cost is low.

Based on this, be necessary the problem low for temperature transmitter detection efficiency, labor intensive is large, a kind of detection system of temperature transmitter is provided.

A detection system for temperature transmitter, comprising: above-mentioned many gears resistance output unit, for according to PT100 thermal resistance calibration table by resistance value be converted to the converter of temperature, for converting electrical signals to the visual instrument of secondary and the comparison means of temperature;

Described many gears resistance output unit, described converter, described comparison means and the visual instrument of described secondary are connected successively, and described many gears resistance output unit is connected with temperature transmitter to be measured respectively with the visual instrument of described secondary.

The detection system of said temperature transmitter, by the input data using the output data of many gears resistance output unit as temperature transmitter to be measured, because many gears resistance output unit can be exported a plurality of resistance automatically, therefore can treat the different ranges of testing temperature transmitter tests, then by the visual instrument of secondary, the electric signal of temperature transmitter to be measured output is converted to temperature and shows, by comparison means, contrast the detection that testing temperature transmitter is treated in the visual instrument of secondary and the realization of converter output data.The different resistance functions of automatic output due to many gears resistance output unit, realize the automatic input of a plurality of gear resistance of one-touch triggering, treat a plurality of range tests of testing temperature forwarder, thereby avoid artificial each parameter to test, improve detection efficiency, reduced manpower and materials.By many gears resistance output unit, export different resistance as the input of temperature transmitter simultaneously, without allowing the charged detection that can realize temperature transmitter of transformer, solved the problem that temperature transmitter is difficult to verification.

Based on this, being necessary, for the problem that in electric substation automation system, measure and control device detection efficiency is low, labor intensive is large, provides the detection system of measure and control device in a kind of electric substation automation system.

A detection system for measure and control device in electric substation automation system, comprising: described many gears resistance output unit, temperature transmitter, for converting electrical signals to the visual instrument of secondary and the comparison means of temperature;

Described many gears resistance output unit, temperature transmitter, the visual instrument of secondary are connected successively with comparison means, and described temperature transmitter is connected with measure and control device in electric substation automation system to be measured respectively with described comparison means.

The detection system of measure and control device in above-mentioned electric substation automation system, by many gears resistance output unit, temperature transmitter and the visual instrument of secondary are connected successively, thus analog temperature data.Because many gears resistance output unit can a key triggers the resistance of a plurality of gears, therefore can simulate a plurality of temperature datas by a key, and then secondary DC quantity corresponding to this temperature data inputted to measure and control device in electric substation automation system to be measured, in the temperature value that comparison means shows the visual instrument of secondary and electric substation automation system to be measured, the data of measure and control device output compare, judge that in described electric substation automation system to be measured, whether measure and control device is abnormal, realize the detection to measure and control device in electric substation automation system to be measured.Avoid the adjusting test of artificial each parameter, reduced manpower and materials, improved testing efficiency.By the visual instrument of many gears resistance output unit, temperature transmitter and secondary, realize and simulate temperature data accurately simultaneously, avoided the inaccurate problem of measure and control device in electric substation automation system.

Accompanying drawing explanation

Fig. 1 is the structural representation of many gears of the utility model resistance output unit embodiment mono-;

Fig. 2 is the structural representation of control loop in many gears of the utility model resistance output unit embodiment bis-;

Fig. 3 is the structural representation of output loop in many gears of the utility model resistance output unit embodiment bis-;

Fig. 4 is the structural representation of the detection system embodiment of the utility model temperature transmitter;

Fig. 5 is the structural representation of the detection system embodiment of measure and control device in the utility model electric substation automation system;

Fig. 6 is control loop structural representation in the utility model five gear resistance output units;

Fig. 7 is output loop structural representation in the utility model five gear resistance output units;

Fig. 8 is the structural representation of the detection system embodiment of measure and control device in the utility model electric substation automation system.

Embodiment

Each embodiment for many gears of the utility model resistance output unit and detection system is described in detail below.

As shown in Figure 1, for the structural representation of many gears of the utility model resistance output unit embodiment mono-, many gears resistance output unit comprises: the first control loop, the second control loop, very first time relay K T1 (accompanying drawing represents with 110), the first resistance R 1 and the second resistance R 2;

Described the first control loop comprises switch Q and the first electromagnetic type relay K1 (accompanying drawing represents with 120), described the first electromagnetic type relay comprises coil K1 (0), the first normally opened contact K1 (1.1), the second normally opened contact K1 (1.2) and the 3rd normally opened contact K1 (1.3), described the second control loop comprises the second electromagnetic type relay K2 (accompanying drawing represents with 130) and the second time relay KT2 (accompanying drawing represents with 140), described the second electromagnetic type relay K2 comprises coil K2 (0) and normally opened contact K2 (1), described the second time relay KT2 comprises coil KT2 (0), the first normally opened contact KT2 (1.1), the second normally opened contact KT2 (1.2) and normally closed contact KT2 (2),

The normally closed contact KT2 (2) of described power input, described switch Q, the coil K1 (0) of described the first electromagnetic type relay, described second time relay is connected successively with power output end, and the first normally opened contact K1 (1.1) of described the first electromagnetic relay and switch Q are connected in parallel;

The second normally opened contact K1 (1.2) of described power input, the first electromagnetic type relay, the coil K2 (0) of the second electromagnetic type relay are, the normally closed contact KT1 (2) of the coil KT2 (0) of second time relay, very first time relay is connected successively with power output end, and the normally opened contact K2 (1) of described the second electromagnetic type relay and the second normally opened contact K1 (1.2) of described the first electromagnetic type relay are connected in parallel;

The first normally opened contact KT2 (1.1) of described power input, described second time relay, the coil KT1 (0) of described very first time relay are connected successively with power output end;

The 3rd normally opened contact K1 (1.3), the first resistance R 1 and the resistance output terminal negative terminal of described resistance output terminal anode, the first electromagnetic type relay are connected successively, and the second normally opened contact KT2 (1.2), the second resistance R 2 and the resistance output terminal negative terminal of described resistance output terminal anode, second time relay are connected successively.

Wherein, above-mentioned normally opened contact, normally closed contact can be contact reed.As long as add certain voltage at coil two ends, in coil, will flow through certain electric current, thereby generation galvanomagnetic effect, armature will overcome the pulling force of return spring under the effect of electromagnetic attracting force to be inhaled to iron core, thereby with moving contact and stationary contact (normally opened contact) adhesive of moving armature.After coil blackout, the suction of electromagnetism also disappears thereupon, and armature will return to original position under the reacting force of spring, makes moving contact and original stationary contact (normally closed contact) adhesive.Adhesive like this, release, thus reached the conducting in circuit, the object of cut-out.For " often open, normally closed " contact of relay, can distinguish like this: the stationary contact in off-state when relay coil is not switched on, is called " normally opened contact "; Stationary contact in on-state is called " normally closed contact ".The relay of mentioning in the utility model has all utilized relay existing capability.

The present embodiment is disclosed is a kind of two gear resistance output units.Specific works principle is as follows:

A1: when the first control loop passes through switch conduction, the first control loop is by the first normally opened contact self-sustaining of the first electromagnetic type relay, the second normally opened contact of the first electromagnetic type relay is controlled the second control loop conducting, the 3rd normally opened contact of the first electromagnetic type relay is controlled the first resistance conducting, output the first resistance;

Wherein, the first resistance conducting is controlled the first resistance and is connected with resistance output terminal.

A2: during the second control loop conducting, the second control loop is by the normally opened contact self-sustaining of the second electromagnetic type relay, the normally closed contact of second time relay is controlled the first control loop and is postponed to disconnect after Preset Time, conducting after the first normally opened contact control very first time relay delay Preset Time of second time relay; The second normally opened contact of second time relay is controlled the second resistance and is postponed conducting after Preset Time.

Wherein, after the second resistance delay Preset Time, conducting is that the second resistance is connected with resistance output terminal after Preset Time.Preset Time is to be determined by the time relay, and concrete time size can be set as required.

In addition, after the first control loop disconnects, the coil of the first electromagnetic type relay is not charged, and the first normally opened contact of the first electromagnetic type relay, the second normally opened contact and the 3rd normally opened contact disconnect, thereby the first resistance and resistance output terminal are disconnected.Although the second normally opened contact of the first electromagnetic type relay in the second control loop disconnects, but because the coil of the second electromagnetic type relay is charged, the normally opened contact of the second electromagnetic type relay is closed, the conducting that keeps the first control loop, so-called the second control loop is by the normally opened contact self-sustaining of the second electromagnetic type relay.

A3: during very first time relay conducting, the normally closed contact of very first time relay is controlled the second control loop and disconnected after Preset Time.

Wherein, switch can be keyswitch, pushbutton switch etc.

As shown in Figure 2, structural representation for control loop in many gears of the utility model resistance output unit embodiment bis-, Fig. 3 is the structural representation (loop that resistance, resistance output terminal form is called output loop) of output loop in many gears of the utility model resistance output unit embodiment bis-, wherein, in order conveniently to check, in figure, specifically do not draw relay, and directly its inner member is drawn in corresponding circuit.

Many gears resistance output unit comprises: the first control loop 210, the second control loop 220, the 3rd control loop, very first time relay K T1, the first resistance R 1, the second resistance R 2 and the 1st are to N resistance R i (1≤i≤N), described the 3rd control loop comprises N sub-control loop (such as the sub-control loop 230 of i), and each sub-control loop is connected in parallel;

Described the first control loop 210 comprises switch Q and the first electromagnetic type relay K1, and described the first electromagnetic type relay K1 comprises coil K1 (0), the first normally opened contact K1 (1.1), the second normally opened contact K1 (1.2) and the 3rd normally opened contact K1 (1.3);

Described the second control loop 220 comprises the second electromagnetic type relay K2 and the second time relay KT2, described the second electromagnetic type relay K2 comprises coil K2 (0) and normally opened contact K2 (1), described the second time relay KT2 comprises coil KT2 (0), the first normally opened contact KT2 (1.1) (annotation: in figure and not shown the first normally opened contact KT2 (1.1), this contact is at the 1st sub-control loop), the second normally opened contact KT2 (1.2) and normally closed contact KT2 (2);

The sub-control loop 230 of i comprises i electromagnetic type relay K _iwith i time relay KT _i, described i electromagnetic type relay comprises coil K _iand normally opened contact K (0) _i(1), described i time relay KT _icomprise coil KT _i(0), the first normally opened contact KT _i(1.1) (annotation: in figure and not shown the first normally opened contact KT _i(1.1), this contact is at the 1st sub-control loop), the second normally opened contact KT _iand normally closed contact KT (1.2) _i(2) (annotation: in figure and not shown normally closed contact KT _i(2), this contact is at i-1 control loop), wherein, i ∈ N;

The coil of described power input, described switch, described the first electromagnetic type relay, the normally closed contact of described second time relay are connected successively with power output end, and the first normally opened contact of described the first electromagnetic relay is connected with switch in parallel;

The second normally opened contact of described power input, the first electromagnetic type relay, the coil of the second electromagnetic type relay, the coil of second time relay, the normally closed contact of the 1st time relay are connected successively with power output end, and the second normally opened contact of the normally opened contact of described the second electromagnetic type relay and described the first electromagnetic type relay is connected in parallel;

Described power input, the first normally opened contact of the i-1 time relay, the coil of i electromagnetic type relay, the coil of the i time relay, the normally closed contact of the i+1 time relay is connected successively with power output end, the normally opened contact of described i electromagnetic type relay and the first normally opened contact of the described i-1 time relay are connected in parallel, wherein, described i=1, the first normally opened contact of the described i-1 time relay is the first normally opened contact of described second time relay, described i=N, the normally closed contact of the described i+1 time relay is the normally closed contact of very first time relay,

The first normally opened contact of described power input, the described N time relay, the coil of described very first time relay are connected successively with power output end;

The 3rd normally opened contact of resistance output terminal anode, the first electromagnetic type relay, the first resistance and resistance output terminal negative terminal are connected successively, the second normally opened contact of described resistance output terminal anode, second time relay, the second resistance and resistance output terminal negative terminal are connected successively, and the second normally opened contact, i resistance and the resistance output terminal negative terminal of described resistance output terminal anode, the i time relay are connected successively.

Wherein, for convenience of description, during i=1, the 1st electromagnetic type relay and the first electromagnetic type relay are not same relays, and the 1st time relay and very first time relay are not same relays, and the 1st resistance and the first resistance are not same resistance.During i=2, in like manner can obtain.

The present embodiment is disclosed is a kind of many gears resistance output unit.The value of resistance can be set as required, can be adjustable resistance, can be also fixed resistance.Specific works principle is as follows:

B1: when the first control loop passes through switch conduction, the first control loop is by the first normally opened contact self-sustaining of the first electromagnetic type relay, the second normally opened contact of the first electromagnetic type relay is controlled the second control loop conducting, the 3rd normally opened contact of the first electromagnetic type relay is controlled the first resistance conducting, output the first resistance;

Wherein, the first resistance conducting is controlled the first resistance and is connected with resistance output terminal.

B2: during the second control loop conducting, the second control loop is by the normally opened contact self-sustaining of the second electromagnetic type relay, the normally closed contact of second time relay is controlled the first control loop and is postponed to disconnect after Preset Time, conducting after the first normally opened contact control the 1st control loop delay Preset Time of second time relay; The second normally opened contact of second time relay is controlled the second resistance and is postponed conducting after Preset Time.

Wherein, after the second resistance delay Preset Time, conducting is that the second resistance is connected with resistance output terminal after Preset Time.Preset Time is to be determined by the time relay, and concrete time size can be set as required.

In addition, after the first control loop disconnects, the coil of the first electromagnetic type relay is not charged, and the first normally opened contact of the first electromagnetic type relay, the second normally opened contact and the 3rd normally opened contact disconnect, thereby the first resistance and resistance output terminal are disconnected.Although the second normally opened contact of the first electromagnetic type relay in the second control loop disconnects, because the coil of the second electromagnetic type relay is charged, the normally opened contact of the second electromagnetic type relay is closed, keeps the conducting of the first control loop.

B3: during the 1st sub-control loop conducting, the 1st sub-control loop is by the normally opened contact self-sustaining of the 1st electromagnetic type relay, the normally closed contact of the 1st time relay is controlled the second control loop and is postponed to disconnect after Preset Time, conducting after the sub-control loop delay of the first normally opened contact control the 2nd Preset Time of the 1st time relay; Conducting after the second normally opened contact control the 1st resistance delay Preset Time of the 1st time relay.

B4: during the sub-control loop conducting of i, the sub-control loop of i is by the normally opened contact self-sustaining of i electromagnetic type relay, the normally closed contact of the i time relay is controlled i-1 control loop and is postponed to disconnect after Preset Time, and the first normally opened contact of the i time relay is controlled i+1 control loop and postponed conducting after Preset Time; The second normally opened contact of the i time relay is controlled i resistance and is postponed conducting after Preset Time.

B5: during the sub-control loop conducting of N, the sub-control loop of N is by the normally opened contact self-sustaining of N electromagnetic type relay, the normally closed contact of the N time relay is controlled N-1 control loop and is postponed to disconnect after Preset Time, conducting after the first normally opened contact control very first time relay delay Preset Time of the N time relay; The second normally opened contact of the N time relay is controlled N resistance and is postponed conducting after Preset Time.

B6: during very first time relay conducting, the normally closed contact of very first time relay is controlled N control loop and disconnected after Preset Time.

Wherein, switch can be keyswitch, pushbutton switch etc.In addition, the coil of the first electromagnetic type relay, the first normally opened contact, the second normally opened contact and the 3rd normally opened contact are all on the first electromagnetic type relay, and described separately is here for clear role separately.Such as, the first normally opened contact of described the first electromagnetic relay is connected the one end that can be understood as switch and is connected with one end of the first normally opened contact of the first electromagnetic relay by line with switch in parallel, the other end of switch is connected with the other end of the first normally opened contact of the first electromagnetic relay by line, thereby the first normally opened contact that can be regarded as the first electromagnetic relay is connected with switch in parallel.Again such as, the 3rd normally opened contact of described resistance output terminal anode, the first electromagnetic type relay, the first resistance and resistance output terminal negative terminal are connected successively and can be understood as resistance output terminal anode and be connected with the 3rd normally opened contact one end of the first electromagnetic type relay by line, the 3rd normally opened contact other end of the first electromagnetic type relay is connected with first resistance one end by line, and the first resistance other end is connected with resistance output terminal negative terminal.Other relays also can be done same understanding, at this, do not repeat one by one.

The time that above-mentioned each time relay arranges is identical.As can be seen here, above-mentioned many gears resistance output unit has N+2 gear, and the size of N+2 resistance (i.e. the first resistance, the second resistance, i resistance) can be made as complete difference, also can be set to part identical.

Above-mentioned many gears resistance output unit, debugs without user one by one by above-mentioned design, can realize many gears of key resistance and automatically export.Simplicity of design, cost is low.

As shown in Figure 4, structural representation for the detection system embodiment of the utility model temperature transmitter, comprising: above-mentioned many gears resistance output unit 410, for according to PT100 thermal resistance calibration table by resistance value be converted to the converter 420 of temperature, for converting electrical signals to the visual instrument 430 of secondary and the comparison means 440 of temperature;

Described many gears resistance output unit 410, described converter 420, described comparison means 440 and the visual instrument 430 of described secondary are connected successively, and described many gears resistance output unit 410 is connected with temperature transmitter to be measured respectively with the visual instrument 430 of described secondary.

The present embodiment utilizes many gears resistance output unit that each resistance is inputted to temperature transmitter to be measured, and the visual instrument of described secondary is converted to the first temperature by the electric signal of temperature transmitter output to be measured and shows.

Here the converter of mentioning is the converter in conventional art, utilizes one of them resistance of converter to turn temperature function, according to PT100 thermal resistance calibration table, the resistance value of described many gears resistance output unit output is converted to temperature.The present embodiment is not that the function of converter is protected, but in detection system, applies to a kind of like this equipment.The temperature of comparison means contrast converter output and the temperature of transmitter to be measured output realize the detection for the treatment of testing temperature transmitter.The function of comparison means has a variety of, and the present embodiment has just utilized wherein a kind of existing capability.

Wherein, the temperature (being called for convenience of description the first temperature) of converter output has one-to-one relationship with resistance, the temperature (being called for convenience of description the second temperature) of temperature transmitter output to be measured has one-to-one relationship with resistance, thereby the first temperature and the second temperature have one-to-one relationship, the first temperature and the second temperature that relatively have respectively one-to-one relationship, realize the detection for the treatment of testing temperature transmitter.

By said system, can realize a key and touch many gears resistance temperature transmitter is detected, improved detection efficiency.

In an embodiment, also comprise warning device therein, described warning device is connected with described comparison means.

Such as, utilize warning device that described the first temperature and described the second temperature are compared, when being greater than predetermined threshold value, error reports to the police.

By warning device is set, can realizes the larger temperature transmitter to be measured of error is reported to the police.It is poor that the second temperature corresponding to the first temperature compared, and in the situation that difference is greater than threshold value, reports to the police.

Therein in an embodiment, described many gears resistance output unit is five gear resistance self-checking devices, and five resistance values of described five gear resistance self-checking device outputs are respectively the resistance value corresponding to 120%, 100%, 50%, 20% and 0 range of temperature transmitter to be measured.Get final product like this key and touch realization to 120% of transmitter to be measured, 100%, 50%, 20% and 0 measurement accuracy detection.

In an embodiment, described temperature transmitter to be measured is temperature current transmitter therein, and the detection system of described temperature transmitter also comprises electric current display instrument, and described electric current display instrument is arranged between the visual instrument of described secondary and temperature transmitter to be measured.Utilize electric current display instrument to show the electric current of temperature transmitter output to be measured, can realize the output of temperature transmitter to be measured is converted to electric current demonstration.

Described temperature transmitter to be measured is temperature voltage transmitter, and the detection system of described temperature transmitter also comprises voltage display instrument, and described voltage display instrument is arranged between the visual instrument of described secondary and temperature transmitter to be measured.Utilize voltage display instrument to show the voltage of temperature transmitter output to be measured, can realize the output of temperature transmitter to be measured is converted to voltage demonstration.

In an embodiment, can also comprise precision resister device therein, precision resister device is connected with temperature transmitter to be measured.Can, to temperature transmitter input precision resister to be measured, realize accuracy detection.

As shown in Figure 5, structural representation for the detection system embodiment of measure and control device in the utility model electric substation automation system, comprising: above-mentioned many gears resistance output unit 510, temperature transmitter 520, for converting electrical signals to the visual instrument 530 of secondary and the comparison means 540 of temperature;

Described many gears resistance output unit 510, temperature transmitter 520, the visual instrument 530 of secondary are connected successively with comparison means 540, and described temperature transmitter 520 is connected with measure and control device in electric substation automation system to be measured respectively with described comparison means 540.

Utilize described many gears resistance output unit that each resistance is inputted to described temperature transmitter;

Utilizing the visual instrument of described secondary that the electric signal of described temperature transmitter output is converted to temperature shows;

In electric substation automation system to be measured, measure and control device receives the secondary DC quantity that transmitter sends, and through a series of processing, thereby demonstrates the Temperature numerical that main-transformer primary equipment is corresponding.

Utilize described comparison means that the data of measure and control device output in the temperature value of the visual instrument demonstration of described secondary and electric substation automation system to be measured are compared, judge that in described electric substation automation system to be measured, whether measure and control device is abnormal.

Therein in an embodiment, described temperature transmitter 520 is temperature current transmitter, in described electric substation automation system, the detection system of measure and control device also comprises electric current display instrument, and described electric current display instrument is arranged between the visual instrument of described secondary and temperature transmitter.

Therein in an embodiment, described temperature transmitter 520 is temperature voltage transmitter, in described electric substation automation system, the detection system of measure and control device also comprises voltage display instrument, and described voltage display instrument is arranged between the visual instrument of described secondary and temperature transmitter.

Certainly, number that can temperature transmitter can be 2.One is temperature current transmitter, and one is temperature voltage transmitter.Many gears resistance output unit, temperature current transmitter, electric current display instrument and the visual instrument of secondary are connected successively, and many gears resistance output unit, temperature voltage transmitter, voltage display instrument and the visual instrument of secondary are connected successively.Can realize the data of simulation are shown by the form of electric current and voltage, so that user checks.

This programme is lifted one of them concrete example that uses and is described, and as shown in Figure 6, is control loop structural representation in the utility model five gear resistance output units, shown in Fig. 7, is output loop structural representation in the utility model five gear resistance output units.

SB is device start button; FA is device involution button; BC is conventional relay, snap action after energising, the instantaneous involution of dead electricity.T1, T2, T3, T4, T5 are the time relay, and can adjust according to actual needs actuation time.This device can be set as 25 seconds.R1, R2, R3, R4, R5 are respectively 5 grades of DC resistances that temperature value is corresponding, and the range ability of supposing temperature transmitter to be measured is 0～150 degree Celsius.Concrete numerical value is as table 1:

Table 1

(1), when Action Button SB connects, start loop 1 (power supply+→ SB → BC1 coil BC1 (0) → normally closed of T1 T1 (2) → power supply-) and connect.BC1 relay coil energising action, starts loop 1 by BC1 the first normally opened contact BC1 (1.1) self-sustaining.BC1 the second normally opened contact BC1 (1.2) closure, output loop 1 (output+→ BC1 the second normally opened contact → R1 → output-) is connected.Output loop resistance is R1.

(2) BC1 the 3rd normally opened contact BC1 (1.3) closure, starts loop 2 (power supply+→ BC1 three normally opened contact → BC2 coil BC2 (0) → T1 coil T1 (0) → T2 normally closed contact T2 (2) → power supply-) and connects.The coil of the coil of BC2 relay, T1 relay is charged, starts loop 2 by BC2 normally opened contact BC2 (1) self-sustaining.T1 time delay 25S action, T1 normally closed contact will start loop 1 to cut off, the involution of BC1 relay coil dead electricity, output loop 1 disconnects.T1 the first normally opened contact T1 (1.1) connects output loop 2 (output+→ T1 the first normally opened contact → R2 → output-).Output loop resistance is R2.

(3) T1 the second normally opened contact T1 (1.2) is closed after 25s action, starts loop 3 (power supply+→ T1 the second normally opened contact → BC3 coil BC3 (0) → T2 coil T2 (0) → T3 normally closed contact T3 (2) → power supply-) and connects.The coil of the coil of BC3 relay, T2 relay is charged, starts loop 3 by BC3 normally opened contact BC3 (1) self-sustaining.T2 normally closed contact time delay 25S action, will start loop 2 and cut off, BC2, the involution of T1 relay coil dead electricity, and output loop 2 disconnects.T2 the first normally opened contact T2 (1.1) connects output loop 3 (output+→ T2 the first normally opened contact → R3 → output-).Output loop resistance is R3.

(4) T2 the second normally opened contact T2 (1.2) is closed in 25s action, starts loop 4 (power supply+→ T2 the second normally opened contact → BC4 coil BC4 (0) → T3 coil T3 (0) → T4 normally closed contact T4 (2) → power supply-) and connects.The coil of the coil of BC4 relay, T3 relay is charged.Start loop 4 by BC4 normally opened contact BC4 (1) self-sustaining.T3 normally closed contact time delay 25S action, will start loop 3 and cut off, BC3, the involution of T2 relay coil dead electricity, and output loop 3 disconnects.T3 the first normally opened contact T3 (1.1) connects output loop 4 (output+→ T3 the first normally opened contact → R4 → output-).Output loop resistance is R4.

(5) T3 the second normally opened contact T3 (1.2) action is closed, starts loop 5 (power supply+→ T3 the second normally opened contact → BC5 coil BC5 (0) → T4 coil T4 (0) → T5 normally closed contact T5 (2) → power supply-) and connects.The coil of the coil of BC5 relay, T4 relay is charged.Start loop 5 by BC5 normally opened contact BC5 (1) self-sustaining.T4 normally closed contact time delay 25S action, will start loop 4 and cut off, BC4, the involution of T3 relay coil dead electricity, and output loop 4 disconnects.T4 the first normally opened contact T4 (1.1) connects output loop 5 (output+→ T4 the first normally opened contact → R5 → output-).Output loop resistance is R5.

(6) T4 the second normally opened contact T4 (1.2) action is closed, starts loop 6 (power supply+→ T4 the second normally opened contact → T5 coil T5 (0) → power supply-) and connects.T5 relay coil is charged.T5 time delay 25S action, the normally closed contact T5 (2) of T5 will start loop 5 to be cut off, and BC5, the involution of T4 relay coil dead electricity start loop 6 and disconnect, and output loop 5 disconnects.Output loop resistance is infinitely great.

As shown in Figure 8, for the structural representation of the detection system embodiment of measure and control device in the utility model electric substation automation system, comprise power supply 810, five gear resistance output units 820, precision resister output unit 830, temperature current transmitter 840, temperature voltage transmitter 850, electric current display instrument 860, voltage display instrument 870, the first two visual instrument 880 and the second two visual instrument 890, comparison means 900.

Wherein, power unit, adopts civil power 220V Alternating Current Power Supply.(2) five gear resistance output units can be realized one-touch shake-up 5 gears input displays temperature automatically, alleviate repeatedly switching circuit workload of maintainer; Precision resister input circuit part, can realize the fixedly various resistance values inputs beyond input pattern of 5 gears, and can correspondingly realize the various different temperatures values of simulation needs, and possesses dirigibility.Transmitter part: the PT100 temperature transmitter of 4～20mA DC current output, the PT100 temperature transmitter of 0～5V direct voltage output.DC quantity display section: 0～20mA DC ammeter display instrument, 0～5V D.C. voltmeter display instrument.Temperature value display section: configure 2 visual instrument of secondary, be convenient to the demonstration directly perceived of device output temperature and check.

This system can realize:

Temperature transmitter verification: temperature current transmitter to be measured is arranged between five gear resistance output units and electric current display instrument, or temperature voltage transmitter to be measured is arranged between five gear resistance output units and voltage display instrument.Can, by the different direct current resistance of analog input, by detecting the DC quantity of temperature transmitter output to be measured, whether meet accuracy requirement, thereby realize transmitter precision checking.

4～20mA DC current analog generator: the built-in DC current transmitter of system, DC current generation output function can be provided, and configuration Phoenix Universal connection terminal, be convenient to access other equipment.

0～5V DC voltage analog generator: the built-in DC voltage transmitter of system, DC voltage generation output function can be provided, and configuration Phoenix Universal connection terminal, be convenient to access other equipment.

Measure and control device in electric substation automation system (dispatch automated system) temperature data analog generator: can be by the different DC resistances of input to transmitter, simulate different secondary DC quantity (such as voltage/current amount), thereby make measure and control device show different temperature datas, realize temperature simulation Presentation Function.And interface is provided, and measure and control device in accessible electric substation automation system, for maintainer's test & check.

Design this system and possess five gear resistance output units, by the one-touch triggering of user, at once realized data acquisition and the verification of temperature transmitter performance curve.Change temperature data in the past and needed situation about manually checking one by one, realized the automatic imitation of various temperature in range ability, thereby the quick verification of the data that realized temperature transmitter, has guaranteed the correctness of measure and control device data in the reliability of equipment and electric substation automation system.This system is easy to carry, operates simple and easyly, has improved field technician's work efficiency.

The above embodiment has only expressed several embodiment of the present utility model, and it describes comparatively concrete and detailed, but can not therefore be interpreted as the restriction to the utility model the scope of the claims.It should be pointed out that for the person of ordinary skill of the art, without departing from the concept of the premise utility, can also make some distortion and improvement, these all belong to protection domain of the present utility model.Therefore, the protection domain of the utility model patent should be as the criterion with claims.

Claims (10)

1. the resistance of gear a more than output unit, is characterized in that, comprising: the first control loop, the second control loop, very first time relay, the first resistance and the second resistance;

Described the first control loop comprises switch and the first electromagnetic type relay, described the first electromagnetic type relay comprises coil, the first normally opened contact, the second normally opened contact and the 3rd normally opened contact, described the second control loop comprises the second electromagnetic type relay and second time relay, described the second electromagnetic type relay comprises coil and normally opened contact, and described second time relay comprises coil, the first normally opened contact, the second normally opened contact and normally closed contact;

The coil of power input, described switch, described the first electromagnetic type relay, the normally closed contact of described second time relay are connected successively with power output end, and the first normally opened contact of described the first electromagnetic relay is connected with switch in parallel;

The second normally opened contact of described power input, the first electromagnetic type relay, the coil of the second electromagnetic type relay, the coil of second time relay, the normally closed contact of very first time relay are connected successively with power output end, and the second normally opened contact of the normally opened contact of described the second electromagnetic type relay and described the first electromagnetic type relay is connected in parallel;

The first normally opened contact of described power input, described second time relay, the coil of described very first time relay are connected successively with power output end;

The 3rd normally opened contact of resistance output terminal anode, the first electromagnetic type relay, the first resistance and resistance output terminal negative terminal are connected successively, and the second normally opened contact of described resistance output terminal anode, second time relay, the second resistance and resistance output terminal negative terminal are connected successively.

2. the output unit of gear resistance more than one kind, it is characterized in that, comprise: the first control loop, the second control loop, the 3rd control loop, very first time relay, the first resistance, the second resistance and the 1st are to N resistance, described the 3rd control loop comprises N sub-control loop, and each sub-control loop is connected in parallel;

Described the first control loop comprises switch and the first electromagnetic type relay, described the first electromagnetic type relay comprises coil, the first normally opened contact, the second normally opened contact and the 3rd normally opened contact, described the second control loop comprises the second electromagnetic type relay and second time relay, described the second electromagnetic type relay comprises coil and normally opened contact, and described second time relay comprises coil, the first normally opened contact, the second normally opened contact and normally closed contact; I sub-control loop comprises i electromagnetic type relay and the i time relay, described i electromagnetic type relay comprises coil and normally opened contact, the described i time relay comprises coil, the first normally opened contact, the second normally opened contact and normally closed contact, wherein, and i ∈ N;

The coil of power input, described switch, described the first electromagnetic type relay, the normally closed contact of described second time relay are connected successively with power output end, and the first normally opened contact of described the first electromagnetic relay is connected with switch in parallel;

The second normally opened contact of described power input, the first electromagnetic type relay, the coil of the second electromagnetic type relay, the coil of second time relay, the normally closed contact of the 1st time relay are connected successively with power output end, and the second normally opened contact of the normally opened contact of described the second electromagnetic type relay and described the first electromagnetic type relay is connected in parallel;

Described power input, the first normally opened contact of the i-1 time relay, the coil of i electromagnetic type relay, the coil of the i time relay, the normally closed contact of the i+1 time relay is connected successively with power output end, the normally opened contact of described i electromagnetic type relay and the first normally opened contact of the described i-1 time relay are connected in parallel, wherein, described i=1, the first normally opened contact of the described i-1 time relay is the first normally opened contact of described second time relay, described i=N, the normally closed contact of the described i+1 time relay is the normally closed contact of very first time relay,

The first normally opened contact of described power input, the described N time relay, the coil of described very first time relay are connected successively with power output end;

The 3rd normally opened contact of resistance output terminal anode, the first electromagnetic type relay, the first resistance and resistance output terminal negative terminal are connected successively, the second normally opened contact of described resistance output terminal anode, second time relay, the second resistance and resistance output terminal negative terminal are connected successively, and the second normally opened contact, i resistance and the resistance output terminal negative terminal of described resistance output terminal anode, the i time relay are connected successively.

3. many gears resistance output unit according to claim 2, is characterized in that,

Described the first resistance is the first adjustable resistance, and described the second resistance is the second adjustable resistance, and described i resistance is i adjustable resistance.

4. the detection system of a temperature transmitter, it is characterized in that, comprising: the many gears resistance output unit described in claim 2 or 3, for according to PT100 thermal resistance calibration table by resistance value be converted to the converter of temperature, for converting electrical signals to the visual instrument of secondary and the comparison means of temperature;

Described many gears resistance output unit, described converter, described comparison means and the visual instrument of described secondary are connected successively, and described many gears resistance output unit is connected with temperature transmitter to be measured respectively with the visual instrument of described secondary.

5. the detection system of temperature transmitter according to claim 4, is characterized in that, also comprises warning device, and described warning device is connected with described comparison means.

6. the detection system of temperature transmitter according to claim 4, it is characterized in that, described many gears resistance output unit is five gear resistance self-checking devices, and five resistance values of described five gear resistance self-checking device outputs are respectively the resistance value corresponding to 120%, 100%, 50%, 20% and 0 range of temperature transmitter to be measured.

7. according to the detection system of the temperature transmitter described in claim 4 to 6 any one, it is characterized in that,

Described temperature transmitter to be measured is temperature current transmitter, and the detection system of described temperature transmitter also comprises electric current display instrument, and described electric current display instrument is arranged between the visual instrument of described secondary and described temperature transmitter to be measured;

Or

Described temperature transmitter to be measured is temperature voltage transmitter, and the detection system of described temperature transmitter also comprises voltage display instrument, and described voltage display instrument is arranged between the visual instrument of described secondary and described temperature transmitter to be measured.

8. the detection system of measure and control device in an electric substation automation system, it is characterized in that, comprising: the many gears resistance output unit described in claim 2 or 3, temperature transmitter, for converting electrical signals to the visual instrument of secondary and the comparison means of temperature;

Described many gears resistance output unit, temperature transmitter, the visual instrument of secondary are connected successively with comparison means, and described temperature transmitter is connected with measure and control device in electric substation automation system to be measured respectively with described comparison means.

9. the detection system of measure and control device in electric substation automation system according to claim 8, it is characterized in that, described temperature transmitter is temperature current transmitter, in described electric substation automation system, the detection system of measure and control device also comprises electric current display instrument, and described electric current display instrument is arranged between the visual instrument of described secondary and temperature transmitter.

10. the detection system of measure and control device in electric substation automation system according to claim 8, it is characterized in that, described temperature transmitter is temperature voltage transmitter, in described electric substation automation system, the detection system of measure and control device also comprises voltage display instrument, and described voltage display instrument is arranged between the visual instrument of described secondary and temperature transmitter.