CN202260484U - Battery energy-saving charging/discharging testing system - Google Patents

Abstract

The utility model relates to the technical field of battery energy-saving charging/discharging testing, and in particular relates to a battery energy-saving charging/discharging testing system. The system is characterized in that when batteries to be tested are in charging states, energy successively passes through a direct current-alternative current conversion unit, a direct current-direct current conversion unit and the batteries from a power grid; when the batteries to be tested are in discharging states, the energy successively passes through the direct current-direct current conversion unit, the direct current-alternative current conversion unit and the power grid; and when the charging energy of the battery is unequal to the discharging energy of the battery, the unbalanced energy part is regulated through the direct current-alternative current conversion unit and the power grid. By using the system, the charging and discharging of the battery can be simultaneously achieved; the energy generated when the battery is discharged is fed back to the power grid so as to realize the cyclic utilization of the energy and achieve the energy-saving effect; partial batteries respectively work in charging and discharging states, the battery energy is transferred between two parts of batteries without passing through the power grid, so that the cyclic utilization efficiency of electric energy is higher, thus the system disclosed by the utility model is energy-saving and integrates charging and discharging, and is simple to operate and high in efficiency.

Description

The energy-conservation charging-discharge tester system of a kind of battery

Technical field

The utility model relates to the energy-conservation charge-discharge test technical field of battery, particularly relates to the energy-conservation charging-discharge tester system of a kind of battery.

Background technology

Rechargeable battery (like lithium battery, lead-acid battery etc.) need change into before dispatching from the factory usually, two steps of partial volume; What is called changes into, partial volume is exactly through charging to battery and discharging; The chemical substance of the both inner pad of battery is fully activated; And through charge and discharge process, judge the capacity of battery, screen, sort out.Traditional change into, the method for partial volume is to charge through battery is received charger, then battery received resistance and discharges, this need consume very big energy, particularly high capacity cell.

In the prior art; The most of still charging/discharging apparatus of original backwardness that adopts of domestic battery production enterprise carries out forming and capacity dividing; Be that charging device and discharge equipment separate; Charging device changes into direct current with civil power and gives powered battery, because charge voltage range is narrow, the battery that generally can only be fit to several types uses; And discharge equipment generally adopts resistance as load, and the energy of battery is consumed through resistance heating; Also have sub-fraction enterprise to adopt thyristor active inversion electric discharge device to discharge, send storage battery energy back to electrical network, but there is following defective in this device: 1) inversion takes place easily overturn phenomenon; 2) harmonic pollution to electrical network is bigger, and the electric current that thyristor active inversion electric discharge device injects electrical network is a square wave, and harmonic content is big; 3) the discharging current ripple coefficient is big.

In order to address the above problem, the patent No. is that the Chinese utility model patent of ZL.200520053515.4 discloses a kind of energy-saving battery charge-discharge system, and its technical scheme adopts the mode that discharges and recharges between electric storage device and the tested battery to realize energy-conservation; And discharge and recharge one; There is following shortcoming in this charge-discharge system: 1) the electric storage device volume is big, and discharges and recharges operating state owing to often being in, and the life-span is short; Need often to upgrade electric storage device, maintenance cost is high; 2) there are unmatched problem in the electric storage device energy and the tested energy content of battery, and when the energy of tested battery greater than the absorbent energy of electric storage device the time, during tested battery discharge, electric storage device voltage will be very high, even burn electric storage device.

Number of patent application is that 200710134763.5 Chinese invention patent discloses a kind of main circuit structure for changing storage battery into charge and discharge; Its technical scheme is to utilize parallel network reverse technology and non-isolation two-way changing technology, has realized that discharging and recharging of battery is integrated, and has realized the energy-conservation of discharge; But this method only is applicable to high-tension battery (being that battery need be connected a plurality of); And battery generally is not connect a plurality ofly when changing into, and thus, the practicality of this method is not strong.

Therefore, to the problem that exists in the prior art, needing badly provides a kind of energy-conservation, efficient, practical, energy-conservation charging-discharge tester system of battery of practicing thrift cost.

Summary of the invention

The purpose of the utility model is to avoid weak point of the prior art and a kind of energy-conservation, efficient, practical, energy-conservation charging-discharge tester system of battery of practicing thrift cost is provided.

The purpose of the utility model realizes through following technical measures:

Provide a kind of battery energy-conservation charging-discharge tester system,Include dc-dc conversion unit and DC-AC converter unit; Each tested battery connects a said dc-dc conversion unit; Said each dc-dc conversion unit is connected with said DC-AC converter unit through common DC bus, and said DC-AC converter unit is connected with electrical network;

When tested battery was in discharge condition, tested battery was discharged into said common DC bus through said dc-dc conversion unit with energy;

When tested battery was in charged state, tested battery absorbed the energy of said common DC bus through said dc-dc conversion unit;

When the tested battery of part is in charged state; When the tested battery of part is in discharge condition; The tested battery that is in discharge condition is discharged into said common DC bus through said dc-dc conversion unit with energy, and the tested battery that is in charged state absorbs the energy of said common DC bus through said dc-dc conversion unit, when tested battery charge and discharge energy is unequal; Wherein

When rechargeable energy during greater than discharge energy, tested battery replenishes the rechargeable energy that absorbs uneven part through said DC-AC converter unit from electrical network;

When discharge energy during greater than rechargeable energy, tested battery feeds back to unnecessary energy in the electrical network through said DC-AC converter unit.

Preferably,Said dc-dc conversion unit is provided with the two-way non-isolated DC-DC transfer circuit of BUCK/BOOST; The two-way non-isolated DC-DC transfer circuit of said BUCK/BOOST includes inductance L 1, resistance R 1, capacitor C 1, FET Q1 and Q2; One end of said inductance L 1 is connected with the positive pole of tested battery; The other end of said inductance L 1 is connected with an end of resistance R 1; The other end of said resistance R 1 is connected with the source electrode of FET Q2, the drain electrode of FET Q1, an end of the drain electrode of said FET Q2 and capacitor C 1, and the other end of capacitor C 1 is connected with the source electrode of FET Q1, the negative pole of tested battery;

Said DC-AC converter unit comprises a Flyback reversible transducer and the first single-phase full bridge reversible transducer; Wherein, A said Flyback reversible transducer comprises transformer T1, FET Q3 and Q4, capacitor C 2; One end of the primary coil of said transformer T1 is connected with an end of capacitor C 1; The other end of the primary coil of said transformer T1 is connected with the drain electrode of FET Q3, and the source electrode of said FET Q3 is connected with the other end of said capacitor C 1, and an end of the secondary coil of said transformer T1 is connected with an end of capacitor C 2; The other end of the secondary coil of said transformer T1 is connected with the drain electrode of FET Q4, and the source electrode of FET Q4 is connected with the other end of capacitor C 2;

The said first single-phase full bridge reversible transducer comprises FET Q5, Q6, Q7, Q8; Inductance L 2; The drain electrode of said FET Q5 is connected with an end of said capacitor C 2, the drain electrode of FET Q7, and the source electrode of FET Q5 is connected with the drain electrode of FET Q6, an end of inductance L 2, and the source electrode of FET Q6 is connected with the other end of capacitor C 2, the source electrode of FET Q8; The drain electrode of FET Q8 is connected with source electrode, the zero line of FET Q7, the other end of inductance L 2 line of starting to exchange fire.

Preferably,Said dc-dc conversion unit is provided with the two-way non-isolated DC-DC transfer circuit of BUCK/BOOST; The two-way non-isolated DC-DC transfer circuit of said BUCK/BOOST includes inductance L 1, resistance R 1, capacitor C 1, FET Q1 and Q2; One end of said inductance L 1 is connected with the positive pole of tested battery; The other end of said inductance L 1 is connected with an end of resistance R 1; The other end of said resistance R 1 is connected with the source electrode of FET Q2, the drain electrode of FET Q1, an end of the drain electrode of said FET Q2 and capacitor C 1, and the other end of capacitor C 1 is connected with the source electrode of FET Q1, the negative pole of tested battery;

Said DC-AC converter unit comprises a said Flyback reversible transducer and three phase full bridge reversible transducer; Wherein, A said Flyback reversible transducer comprises transformer T1, FET Q3 and Q4, capacitor C 2; One end of the primary coil of said transformer T1 is connected with an end of capacitor C 1; The other end of the primary coil of said transformer T1 is connected with the drain electrode of FET Q3, and the source electrode of said FET Q3 is connected with the other end of said capacitor C 1, and an end of the secondary coil of said transformer T1 is connected with an end of capacitor C 2; The other end of the secondary coil of said transformer T1 is connected with the drain electrode of FET Q4, and the source electrode of FET Q4 is connected with the other end of capacitor C 2;

Said three phase full bridge reversible transducer comprises FET Q5, Q6, Q7, Q8, Q9, Q10; Inductance L 2, L3, L4; The drain electrode of said FET Q5 is connected with an end of said capacitor C 2, the drain electrode of FET Q7, the drain electrode of FET Q9; The source electrode of FET Q5 is connected with the drain electrode of FET Q6, an end of inductance L 2, and the source electrode of FET Q6 is connected with the other end of capacitor C 2, the source electrode of FET Q8, the source electrode of FET Q10, and the drain electrode of FET Q8 is connected with the source electrode of FET Q7, an end of inductance L 3; The drain electrode of FET Q10 is connected with the source electrode of FET Q9, an end of inductance L 4; The other end of said inductance L 4 is connected with AC power C, and the other end of inductance L 2 is connected with AC power A, and the other end of inductance L 3 is connected with AC power B.

Preferably,Said dc-dc conversion unit is provided with the two-way non-isolated DC-DC transfer circuit of BUCK/BOOST; The two-way non-isolated DC-DC transfer circuit of said BUCK/BOOST includes inductance L 1, resistance R 1, capacitor C 1, FET Q1 and Q2; One end of said inductance L 1 is connected with the positive pole of tested battery; The other end of said inductance L 1 is connected with an end of resistance R 1; The other end of said resistance R 1 is connected with the source electrode of FET Q2, the drain electrode of FET Q1, an end of the drain electrode of said FET Q2 and capacitor C 1, and the other end of capacitor C 1 is connected with the source electrode of FET Q1, the negative pole of tested battery;

Said DC-AC converter unit comprises the first single-phase full bridge converter and power frequency isolating transformer T3; The said first single-phase full bridge reversible transducer comprises FET Q5, Q6, Q7, Q8; Inductance L 2; The drain electrode of said FET Q5 is connected with an end of said capacitor C 1, the drain electrode of FET Q7; The source electrode of FET Q5 is connected with the drain electrode of FET Q6, an end of inductance L 2; The source electrode of FET Q6 is connected with the other end of capacitor C 1, the source electrode of FET Q8, and an end of the source electrode of the drain electrode of FET Q8 and FET Q7, the primary coil of power frequency isolating transformer T3 is connected, and the other end of inductance L 2 is connected with the other end of the primary coil of power frequency isolating transformer T3; One end of the secondary coil of said power frequency isolating transformer T3 connects live wire, and the other end of the secondary coil of said power frequency isolating transformer T3 connects zero line.

Preferably,Said dc-dc conversion unit is the 2nd Flyback reversible transducer; Said the 2nd Flyback reversible transducer comprises transformer T11, FET Q13 and Q14, capacitor C 12, resistance R 2; One end of the primary coil of said transformer T11 is connected with the positive pole of tested battery; The other end of the primary coil of said transformer T11 is connected with the drain electrode of FET Q13; The source electrode of said FET Q13 is connected with an end of resistance R 2, and an end of the secondary coil of said transformer T11 is connected with an end of capacitor C 12, and the other end of the secondary coil of said transformer T11 is connected with the drain electrode of FET Q14; The source electrode of FET Q14 is connected with the other end of capacitor C 12, and the negative pole that the other end of resistance R 2 connects tested battery connects;

Said DC-AC converter unit comprises the BUCK/BOOST reversible transducer and the second single-phase full bridge reversible transducer; Wherein, Said BUCK/BOOST reversible transducer comprises inductance L 11, resistance R 11, capacitor C 11, FET Q11 and Q12; One end of said inductance L 11 is connected with an end of said capacitor C 12, and the other end of said inductance L 11 is connected with an end of resistance R 11, and the other end of said resistance R 11 is connected with the source electrode of FET Q12, the drain electrode of FET Q11; One end of the drain electrode of said FET Q12 and capacitor C 11, the other end of capacitor C 11 is connected with the source electrode of FET Q11, the other end of capacitor C 12;

The said second single-phase full bridge reversible transducer comprises FET Q15, Q16, Q17, Q18; Inductance L 12; The drain electrode of said FET Q15 is connected with an end of said capacitor C 11, the drain electrode of FET Q17; The source electrode of FET Q15 is connected with the drain electrode of FET Q16, an end of inductance L 12; The source electrode of FET Q16 is connected with the other end of capacitor C 11, the source electrode of FET Q18, and the drain electrode of FET Q18 is connected with source electrode, the zero line of FET Q17, the other end of inductance L 12 line of starting to exchange fire.

The beneficial effect of the utility model:

The energy-conservation charging-discharge tester system of a kind of battery of the utility model; When tested battery all is in charged state; Energy passes through DC-AC converter unit, dc-dc conversion unit, battery successively from electrical network, and promptly the electrical network energy charges the battery through behind the test macro; When tested battery all was in discharge condition, energy passed through dc-dc conversion unit, DC-AC converter unit, electrical network successively from battery, and promptly battery discharging energy turns back in the electrical network through behind the test macro; When the part battery is in charged state; When the part battery was in discharge condition, the battery that is in discharge condition was discharged into common DC bus through the dc-dc conversion unit with energy, and the battery that is in charged state absorbs the energy on the common DC bus through the dc-dc conversion unit; When the battery charging and discharging energy is unequal; Regulate the unbalanced part of energy through DC-AC converter unit and electrical network, promptly, replenish the partial charging energy from electrical network through the DC-AC converter unit when rechargeable energy during greater than discharge energy; When discharge energy during, unnecessary energy is fed back in the electrical network through the DC-AC converter unit greater than rechargeable energy.

The utility model has been realized charging and discharge to battery simultaneously through bi-directional electric power electronic variable technology, both can be used as charger and has charged the battery; Also can be used as discharge equipment and the electric weight of battery is put in the electrical network goes, thereby the electric energy during with tested battery discharge feeds back in the electrical network, realizes the recycle of energy; Reach energy-saving effect, let the tested battery of part work in charging and discharge condition respectively, the tested energy content of battery is transmitted mutually between the tested battery of two parts; Without electrical network, the efficient of recycle electric energy is higher, and is not only energy-conservation; And discharge and recharge one, simple to operate efficient.

Description of drawings

Utilize accompanying drawing that the utility model is further specified, but the content in the accompanying drawing does not constitute any restriction to the utility model.

Fig. 1 is the functional-block diagram of embodiment 1 of the energy-conservation charging-discharge tester system of a kind of battery of the utility model.

Fig. 2 is the circuit diagram of embodiment 2 of the energy-conservation charging-discharge tester system of a kind of battery of the utility model.

Fig. 3 is the circuit diagram of embodiment 3 of the energy-conservation charging-discharge tester system of a kind of battery of the utility model.

Fig. 4 is the circuit diagram of embodiment 4 of the energy-conservation charging-discharge tester system of a kind of battery of the utility model.

Fig. 5 is the circuit diagram of embodiment 5 of the energy-conservation charging-discharge tester system of a kind of battery of the utility model.

In Fig. 1 to Fig. 5, include:

Dc-dc conversion unit 1, DC-AC converter unit 2;

The one Flyback reversible transducer 21, the first single-phase full bridge reversible transducer 22;

Three phase full bridge reversible transducer 23;

BUCK/BOOST reversible transducer 25, the second single-phase full bridge reversible transducer 26.

Embodiment

In conjunction with following examples the utility model is described further.

Embodiment 1

The energy-conservation charging-discharge tester system of a kind of battery of the utility model is as shown in Figure 1; Include tested battery, dc-dc conversion unit and DC-AC converter unit 1; Each tested battery connects a dc-dc conversion unit 1; Dc-dc conversion unit 1 is connected with DC-AC converter unit 2 through common DC bus, and DC-AC converter unit 2 is connected with electrical network.

There are three kinds of working methods in this system:

1. when all tested batteries all were in charged state, energy passed through DC-AC converter unit 2, dc-dc conversion unit 1, tested battery successively from electrical network, and promptly the electrical network energy is through giving tested battery charge behind the test macro;

2. when all tested batteries were in discharge condition, energy passed through dc-dc conversion unit 1, DC-AC converter unit 2, electrical network successively from tested battery, and promptly tested battery discharging energy turns back in the electrical network through behind the test macro;

3. work as the tested battery of part and be in charged state; When the tested battery of part is in discharge condition; The tested battery that is in discharge condition is discharged into common DC bus through dc-dc conversion unit 1 with energy; The tested battery that is in charged state is through the energy that dc-dc conversion unit 1 absorbs on the common DC bus, and the tested battery that promptly charges discharges and recharges mutually through dc-dc conversion unit 1 with the tested battery of discharge.

When tested battery charge and discharge energy is unequal, regulate the unbalanced part of energy through DC-AC converter unit 2 and electrical network.Wherein, when rechargeable energy during, replenish the partial charging energy from electrical network through DC-AC converter unit 2 greater than discharge energy; When discharge energy during, unnecessary energy is fed back in the electrical network through DC-AC converter unit 2 greater than rechargeable energy.

The energy-conservation charging-discharge tester system of the battery of the utility model has been realized charging and the discharge to battery simultaneously, both can be used as charger and has charged the battery, and can be used as discharge equipment again and the electric weight of battery is put in the electrical network goes; Thereby the electric energy during with tested battery discharge feeds back in the electrical network, realizes the recycle of energy, reaches energy-saving effect; Let the tested battery of part work in charging and discharge condition respectively, the tested energy content of battery is transmitted, between the tested battery of two parts mutually without electrical network; The efficient of recycle electric energy is higher; Not only energy-conservation, and discharge and recharge one, simple to operate efficient.

Embodiment 2

The energy-conservation charging-discharge tester system of a kind of battery of present embodiment is as shown in Figure 2, and on the basis of embodiment 1, unaccounted in the present embodiment characteristic adopts the explanation among the embodiment 1, no longer gives unnecessary details at this.The difference of present embodiment and embodiment 1 is:

Dc-dc conversion unit 1 is provided with the two-way non-isolated DC-DC transfer circuit of BUCK/BOOST; The two-way non-isolated DC-DC transfer circuit of BUCK/BOOST includes inductance L 1, resistance R 1, capacitor C 1, FET Q1 and Q2; One end of inductance L 1 is connected with the positive pole of tested battery; The other end of inductance L 1 is connected with an end of resistance R 1; The other end of resistance R 1 is connected with the source electrode of FET Q2, the drain electrode of FET Q1, an end of the drain electrode of FET Q2 and capacitor C 1, and the other end of capacitor C 1 is connected with the source electrode of FET Q1, the negative pole of tested battery;

DC-AC converter unit 2 comprises a Flyback reversible transducer 21 and the first single-phase full bridge reversible transducer 22; Wherein, The one Flyback reversible transducer 21 comprises transformer T1, FET Q3 and Q4, capacitor C 2, and an end of the primary coil of transformer T1 is connected with an end of capacitor C 1, and the other end of the primary coil of transformer T1 is connected with the drain electrode of FET Q3; The source electrode of FET Q3 is connected with the other end of capacitor C 1; One end of the secondary coil of transformer T1 is connected with an end of capacitor C 2, and the other end of the secondary coil of transformer T1 is connected with the drain electrode of FET Q4, and the source electrode of FET Q4 is connected with the other end of capacitor C 2;

The first single-phase full bridge reversible transducer 22 comprises FET Q5, Q6, Q7, Q8; Inductance L 2; The drain electrode of FET Q5 is connected with an end of capacitor C 2, the drain electrode of FET Q7, and the source electrode of FET Q5 is connected with the drain electrode of FET Q6, an end of inductance L 2, and the source electrode of FET Q6 is connected with the other end of capacitor C 2, the source electrode of FET Q8; The drain electrode of FET Q8 is connected with source electrode, the zero line of FET Q7, the other end of inductance L 2 line of starting to exchange fire.

Embodiment 3

The energy-conservation charging-discharge tester system of a kind of battery of present embodiment is as shown in Figure 3, and on the basis of embodiment 1, unaccounted in the present embodiment characteristic adopts the explanation among the embodiment 1, no longer gives unnecessary details at this.The difference of present embodiment and embodiment 1 is:

Dc-dc conversion unit 1 is provided with the two-way non-isolated DC-DC transfer circuit of BUCK/BOOST; The two-way non-isolated DC-DC transfer circuit of BUCK/BOOST includes inductance L 1, resistance R 1, capacitor C 1, FET Q1 and Q2; One end of inductance L 1 is connected with the positive pole of tested battery; The other end of inductance L 1 is connected with an end of resistance R 1; The other end of resistance R 1 is connected with the source electrode of FET Q2, the drain electrode of FET Q1, an end of the drain electrode of FET Q2 and capacitor C 1, and the other end of capacitor C 1 is connected with the source electrode of FET Q1, the negative pole of tested battery;

DC-AC converter unit 2 comprises a Flyback reversible transducer 21 and three phase full bridge reversible transducer 23; Wherein, The one Flyback reversible transducer 21 comprises transformer T1, FET Q3 and Q4, capacitor C 2, and an end of the primary coil of transformer T1 is connected with an end of capacitor C 1, and the other end of the primary coil of transformer T1 is connected with the drain electrode of FET Q3; The source electrode of FET Q3 is connected with the other end of capacitor C 1; One end of the secondary coil of transformer T1 is connected with an end of capacitor C 2, and the other end of the secondary coil of transformer T1 is connected with the drain electrode of FET Q4, and the source electrode of FET Q4 is connected with the other end of capacitor C 2;

Three phase full bridge reversible transducer 23 comprises FET Q5, Q6, Q7, Q8, Q9, Q10; Inductance L 2, L3, L4; The drain electrode of FET Q5 is connected with an end of capacitor C 2, the drain electrode of FET Q7, the drain electrode of FET Q9; The source electrode of FET Q5 is connected with the drain electrode of FET Q6, an end of inductance L 2, and the source electrode of FET Q6 is connected with the other end of capacitor C 2, the source electrode of FET Q8, the source electrode of FET Q10, and the drain electrode of FET Q8 is connected with the source electrode of FET Q7, an end of inductance L 3; The drain electrode of FET Q10 is connected with the source electrode of FET Q9, an end of inductance L 4; The other end of inductance L 4 is connected with AC power C, and the other end of inductance L 2 is connected with AC power A, and the other end of inductance L 3 is connected with AC power B.

Embodiment 4

The energy-conservation charging-discharge tester system of a kind of battery of present embodiment is as shown in Figure 4, and on the basis of embodiment 1, unaccounted in the present embodiment characteristic adopts the explanation among the embodiment 1, no longer gives unnecessary details at this.The difference of present embodiment and embodiment 1 is:

Dc-dc conversion unit 1 is provided with the two-way non-isolated DC-DC transfer circuit of BUCK/BOOST; The two-way non-isolated DC-DC transfer circuit of BUCK/BOOST includes inductance L 1, resistance R 1, capacitor C 1, FET Q1 and Q2; One end of inductance L 1 is connected with the positive pole of tested battery; The other end of inductance L 1 is connected with an end of resistance R 1; The other end of resistance R 1 is connected with the source electrode of FET Q2, the drain electrode of FET Q1, an end of the drain electrode of FET Q2 and capacitor C 1, and the other end of capacitor C 1 is connected with the source electrode of FET Q1, the negative pole of tested battery;

DC-AC converter unit 2 comprises the first single-phase full bridge converter 22 and power frequency isolating transformer T3; The first single-phase full bridge reversible transducer 22 comprises FET Q5, Q6, Q7, Q8; Inductance L 2; The drain electrode of FET Q5 is connected with an end of capacitor C 1, the drain electrode of FET Q7, and the source electrode of FET Q5 is connected with the drain electrode of FET Q6, an end of inductance L 2, and the source electrode of FET Q6 is connected with the other end of capacitor C 1, the source electrode of FET Q8; One end of the source electrode of the drain electrode of FET Q8 and FET Q7, the primary coil of power frequency isolating transformer T3 is connected; The other end of inductance L 2 is connected with the other end of the primary coil of power frequency isolating transformer T3, and an end of the secondary coil of power frequency isolating transformer T3 connects live wire, and the other end of the secondary coil of power frequency isolating transformer T3 connects zero line.

Embodiment 5

The energy-conservation charging-discharge tester system of a kind of battery of present embodiment is as shown in Figure 5, and on the basis of embodiment 1, unaccounted in the present embodiment characteristic adopts the explanation among the embodiment 1, no longer gives unnecessary details at this.The difference of present embodiment and embodiment 1 is:

Dc-dc conversion unit 1 is the 2nd Flyback reversible transducer; The 2nd Flyback reversible transducer comprises transformer T11, FET Q13 and Q14, capacitor C 12, resistance R 2; One end of the primary coil of transformer T11 is connected with the positive pole of tested battery; The other end of the primary coil of transformer T11 is connected with the drain electrode of FET Q13; The source electrode of FET Q13 is connected with an end of resistance R 2, and an end of the secondary coil of transformer T11 is connected with an end of capacitor C 12, and the other end of the secondary coil of transformer T11 is connected with the drain electrode of FET Q14; The source electrode of FET Q14 is connected with the other end of capacitor C 12, and the negative pole that the other end of resistance R 2 connects tested battery connects;

DC-AC converter unit 2 comprises the BUCK/BOOST reversible transducer 25 and the second single-phase full bridge reversible transducer 26; Wherein, BUCK/BOOST reversible transducer 25 comprises inductance L 11, resistance R 11, capacitor C 11, FET Q11 and Q12; One end of inductance L 11 is connected with an end of capacitor C 12, and the other end of inductance L 11 is connected with an end of resistance R 11, and the other end of resistance R 11 is connected with the source electrode of FET Q12, the drain electrode of FET Q11; One end of the drain electrode of FET Q12 and capacitor C 11, the other end of capacitor C 11 is connected with the source electrode of FET Q11, the other end of capacitor C 12; The second single-phase full bridge reversible transducer 26 comprises FET Q15, Q16, Q17, Q18; Inductance L 12; The drain electrode of FET Q15 is connected with an end of capacitor C 11, the drain electrode of FET Q17; The source electrode of FET Q15 is connected with the drain electrode of FET Q16, an end of inductance L 12; The source electrode of FET Q16 is connected with the other end of capacitor C 11, the source electrode of FET Q18, and the drain electrode of FET Q18 is connected with source electrode, the zero line of FET Q17, the other end of inductance L 12 line of starting to exchange fire.

Should be noted that at last; Above embodiment only be used to explain the utility model technical scheme but not to the restriction of the utility model protection range; Although the utility model has been done detailed description with reference to preferred embodiment; Those of ordinary skill in the art should be appreciated that and can make amendment or be equal to replacement the technical scheme of the utility model, and do not break away from the essence and the scope of the utility model technical scheme.

Claims (5)

1. The energy-conservation charging-discharge tester system of a kind of battery,It is characterized in that: include dc-dc conversion unit and DC-AC converter unit; Each tested battery connects a said dc-dc conversion unit; Said each dc-dc conversion unit is connected with said DC-AC converter unit through common DC bus, and said DC-AC converter unit is connected with electrical network;

When tested battery was in discharge condition, tested battery was discharged into said common DC bus through said dc-dc conversion unit with energy;

When tested battery was in charged state, tested battery absorbed the energy of said common DC bus through said dc-dc conversion unit;

When the tested battery of part is in charged state; When the tested battery of part is in discharge condition; The tested battery that is in discharge condition is discharged into said common DC bus through said dc-dc conversion unit with energy, and the tested battery that is in charged state absorbs the energy of said common DC bus through said dc-dc conversion unit, when tested battery charge and discharge energy is unequal; Wherein

When rechargeable energy during greater than discharge energy, tested battery replenishes the rechargeable energy that absorbs uneven part through said DC-AC converter unit from electrical network;

When discharge energy during greater than rechargeable energy, tested battery feeds back to unnecessary energy in the electrical network through said DC-AC converter unit.

2. the energy-conservation charging-discharge tester system of a kind of battery according to claim 1; It is characterized in that: said dc-dc conversion unit is provided with the two-way non-isolated DC-DC transfer circuit of BUCK/BOOST; The two-way non-isolated DC-DC transfer circuit of said BUCK/BOOST includes inductance L 1, resistance R 1, capacitor C 1, FET Q1 and Q2; One end of said inductance L 1 is connected with the positive pole of tested battery; The other end of said inductance L 1 is connected with an end of resistance R 1; The other end of said resistance R 1 is connected with the source electrode of FET Q2, the drain electrode of FET Q1, an end of the drain electrode of said FET Q2 and capacitor C 1, and the other end of capacitor C 1 is connected with the source electrode of FET Q1, the negative pole of tested battery;

Said DC-AC converter unit comprises a Flyback reversible transducer and the first single-phase full bridge reversible transducer; Wherein, A said Flyback reversible transducer comprises transformer T1, FET Q3 and Q4, capacitor C 2; One end of the primary coil of said transformer T1 is connected with the drain electrode of said FET Q2; The other end of the primary coil of said transformer T1 is connected with the drain electrode of FET Q3, and the source electrode of said FET Q3 is connected with the other end of said capacitor C 1, and an end of the secondary coil of said transformer T1 is connected with an end of capacitor C 2; The other end of the secondary coil of said transformer T1 is connected with the drain electrode of FET Q4, and the source electrode of FET Q4 is connected with the other end of capacitor C 2;

The said first single-phase full bridge reversible transducer comprises FET Q5, Q6, Q7, Q8; Inductance L 2; The drain electrode of said FET Q5 is connected with an end of said capacitor C 2, the drain electrode of FET Q7, and the source electrode of FET Q5 is connected with the drain electrode of FET Q6, an end of inductance L 2, and the source electrode of FET Q6 is connected with the other end of capacitor C 2, the source electrode of FET Q8; The drain electrode of FET Q8 is connected with source electrode, the zero line of FET Q7, the other end of inductance L 2 line of starting to exchange fire.

3. the energy-conservation charging-discharge tester system of stating according to claim 1 of a kind of battery; It is characterized in that: said dc-dc conversion unit is provided with the two-way non-isolated DC-DC transfer circuit of BUCK/BOOST; The two-way non-isolated DC-DC transfer circuit of said BUCK/BOOST includes inductance L 1, resistance R 1, capacitor C 1, FET Q1 and Q2; One end of said inductance L 1 is connected with the positive pole of tested battery; The other end of said inductance L 1 is connected with an end of resistance R 1; The other end of said resistance R 1 is connected with the source electrode of FET Q2, the drain electrode of FET Q1, an end of the drain electrode of said FET Q2 and capacitor C 1, and the other end of capacitor C 1 is connected with the source electrode of FET Q1, the negative pole of tested battery;

Said DC-AC converter unit comprises a Flyback reversible transducer and three phase full bridge reversible transducer; Wherein, A said Flyback reversible transducer comprises transformer T1, FET Q3 and Q4, capacitor C 2; One end of the primary coil of said transformer T1 is connected with an end of capacitor C 1; The other end of the primary coil of said transformer T1 is connected with the drain electrode of FET Q3, and the source electrode of said FET Q3 is connected with the other end of said capacitor C 1, and an end of the secondary coil of said transformer T1 is connected with an end of capacitor C 2; The other end of the secondary coil of said transformer T1 is connected with the drain electrode of FET Q4, and the source electrode of FET Q4 is connected with the other end of capacitor C 2;

Said three phase full bridge reversible transducer comprises FET Q5, Q6, Q7, Q8, Q9, Q10; Inductance L 2, L3, L4; The drain electrode of said FET Q5 is connected with an end of said capacitor C 2, the drain electrode of FET Q7, the drain electrode of FET Q9; The source electrode of FET Q5 is connected with the drain electrode of FET Q6, an end of inductance L 2, and the source electrode of FET Q6 is connected with the other end of capacitor C 2, the source electrode of FET Q8, the source electrode of FET Q10, and the drain electrode of FET Q8 is connected with the source electrode of FET Q7, an end of inductance L 3; The drain electrode of FET Q10 is connected with the source electrode of FET Q9, an end of inductance L 4; The other end of said inductance L 4 is connected with AC power C, and the other end of inductance L 2 is connected with AC power A, and the other end of inductance L 3 is connected with AC power B.

4. the energy-conservation charging-discharge tester system of stating according to claim 1 of a kind of battery; It is characterized in that: said dc-dc conversion unit is provided with the two-way non-isolated DC-DC transfer circuit of BUCK/BOOST; The two-way non-isolated DC-DC transfer circuit of said BUCK/BOOST includes inductance L 1, resistance R 1, capacitor C 1, FET Q1 and Q2; One end of said inductance L 1 is connected with the positive pole of tested battery; The other end of said inductance L 1 is connected with an end of resistance R 1; The other end of said resistance R 1 is connected with the source electrode of FET Q2, the drain electrode of FET Q1, an end of the drain electrode of said FET Q2 and capacitor C 1, and the other end of capacitor C 1 is connected with the source electrode of FET Q1, the negative pole of tested battery;

Said DC-AC converter unit comprises the first single-phase full bridge converter and power frequency isolating transformer T3; The said first single-phase full bridge reversible transducer comprises FET Q5, Q6, Q7, Q8; Inductance L 2; The drain electrode of said FET Q5 is connected with an end of said capacitor C 1, the drain electrode of FET Q7; The source electrode of FET Q5 is connected with the drain electrode of FET Q16, an end of inductance L 2; The source electrode of FET Q16 is connected with the other end of capacitor C 1, the source electrode of FET Q8, and an end of the source electrode of the drain electrode of FET Q8 and FET Q7, the primary coil of power frequency isolating transformer T3 is connected, and the other end of inductance L 2 is connected with the other end of the primary coil of power frequency isolating transformer T3; One end of the secondary coil of said power frequency isolating transformer T3 connects live wire, and the other end of the secondary coil of said power frequency isolating transformer T3 connects zero line.

5. the energy-conservation charging-discharge tester system of a kind of battery according to claim 1; It is characterized in that: said dc-dc conversion unit is the 2nd Flyback reversible transducer; Said the 2nd Flyback reversible transducer comprises transformer T11, FET Q13 and Q14, capacitor C 12, resistance R 2; One end of the primary coil of said transformer T11 is connected with the positive pole of tested battery; The other end of the primary coil of said transformer T11 is connected with the drain electrode of FET Q13; The source electrode of said FET Q13 is connected with an end of resistance R 2, and an end of the secondary coil of said transformer T11 is connected with an end of capacitor C 12, and the other end of the secondary coil of said transformer T11 is connected with the drain electrode of FET Q14; The source electrode of FET Q14 is connected with the other end of capacitor C 12, and the negative pole that the other end of resistance R 2 connects tested battery connects;

Said DC-AC converter unit comprises the BUCK/BOOST reversible transducer and the second single-phase full bridge reversible transducer; Wherein, Said BUCK/BOOST reversible transducer comprises inductance L 11, resistance R 11, capacitor C 11, FET Q11 and Q12; One end of said inductance L 11 is connected with an end of said capacitor C 12, and the other end of said inductance L 11 is connected with an end of resistance R 11, and the other end of said resistance R 11 is connected with the source electrode of FET Q12, the drain electrode of FET Q11; One end of the drain electrode of said FET Q12 and capacitor C 11, the other end of capacitor C 11 is connected with the source electrode of FET Q11, the other end of capacitor C 12;

The said second single-phase full bridge reversible transducer comprises FET Q15, Q16, Q17, Q18; Inductance L 12; The drain electrode of said FET Q15 is connected with an end of said capacitor C 11, the drain electrode of FET Q17; The source electrode of FET Q15 is connected with the drain electrode of FET Q16, an end of inductance L 12; The source electrode of FET Q16 is connected with the other end of capacitor C 11, the source electrode of FET Q18, and the drain electrode of FET Q18 is connected with source electrode, the zero line of FET Q17, the other end of inductance L 12 line of starting to exchange fire.

Images