The present invention relates to a charge and discharge balancing circuit, and in particular, a charge and discharge balancing circuit for a storage battery set.
The voltage and capacity of a single storage battery (such as NiMH battery, lead-acid battery, lithium battery, etc.) are limited, and therefore a storage battery set constituted of storage batteries connected in series is required for use in many electric appliances. However, the electrical characteristics (such as voltage, current, capacity (ampere-hour), etc.) of each storage battery of the storage battery set are slightly different from one another, and therefore each of the storage batteries connected in series cannot provide the same output voltage and current, which causes a power supply balancing issue among each storage battery. Also, as the electrical characteristics of each storage battery are different from one another, the cycle life will also be different from one another after many times of charge and discharge; however, the cycle life of the whole storage battery set is depending on the storage battery whose cycle life is shortest.
In order to extend the cycle life of the storage battery set, there are lossless and balanced charge and discharge methods proposed to be applied to each storage battery of the storage battery set, which currently include the following methods.
A method is to provide a balancing circuit connected in parallel to each storage battery of the storage battery set so as to divide the current. When a storage battery comes to a complete charge first, the balancing circuit can avoid this storage battery from being overcharged by converting the surplus energy into thermal energy, and the other storage batteries that have not been completely charged are continuously charged. The balancing circuit of this method is simple but will cause too much loss of energy, and therefore is not adapted to a quick charge system for the storage battery.
Another method is that each storage battery is discharged to a load one by one to the same level before the storage battery set is charged, and then is charged with a constant current to ensure an accurate balancing state among each storage battery. However, for the storage battery set, as each storage battery has different electrical characteristics from one another, the discharge of each storage battery is difficult to achieve an ideal consistence effect. Even if the discharge can achieve a consistence effect, there will also be a new unbalancing phenomenon occurring during the charging.
Another method is utilizing the time sharing principle, which makes extra currents flow into the storage battery having a lower voltage by means of the control and switching of a switch component, so as to charge the storage battery set uniformly. The charging efficiency of this method is high, but the control of charge is more complicated.
Yet another method is that the storage battery set is controlled by a single chip and each storage battery has a separate module. Each storage battery is charged by its own module according to a predetermined procedure, and is automatically powered off after the charging is completed. This method is simple, but will increase the cost of the system if there are too many storage batteries and is disadvantageous in reducing the size of the system.
The present invention provides a charge and discharge balancing circuit for a storage battery set, which can make each storage battery achieve a balanced charge and discharge by a simple control of a switch set and the charge and discharge between the storage battery and the electricity storage component, thereby extending the cycle life of the storage battery set.
In a first aspect, the present invention provides a charge and discharge balancing circuit for a storage battery set, the storage battery set connected in parallel to a load and constituted of n storage batteries connected in series where n is an integer of 2 or above, the circuit comprising:
In a second aspect, the present invention provides a charge and discharge balancing circuit for a storage battery set, the storage battery set connected in parallel to a load and constituted of n storage batteries connected in series where n is an integer of 3 or above, the circuit comprising:
In the charge and discharge balancing circuit for a storage battery set according to the first or second aspect, the electricity storage component is one of a capacitor and a supercapacitor.
In the charge and discharge balancing circuit for a storage battery set according to the first aspect, the frequency of the pulse generator for controlling each switch depends on the condition that the charging and discharging voltages of each storage battery and electricity storage component connected in parallel are the same.
In the charge and discharge balancing circuit for a storage battery set according to the second aspect, the first frequency of the pulse generator for controlling each switch depends on the condition that the charging and discharging voltages of each storage battery and electricity storage component connected in parallel are the same, the second frequency of the pulse generator for controlling each switch depends on the condition that the charging and discharging voltages of at least two electricity storage components of the electricity storage component set and at least two electricity storage components of the at least one parallel electricity storage component set are the same, and the pulse generator divides the first frequency to obtain the second frequency.
Several preferred embodiments according to the present invention will be described below with reference to the accompanying drawings.
Each of n switches SS1, SS2, SS3, . . . SSn has a switching node S1, a switching node S2 and a common node C. The switching node S2 of the first switch SS1 and the switching node S1 of the second switch SS2 are electrically connected; the switching node S2 of the second switch SS2 and the switching node S1 of the third switch SS3 are electrically connected; the switching node S2 of the n−1th switch SSn-1 and the switching node S1 of the nth switch SSn are electrically connected; and so on. These n switches SS1, SS2, SS3, . . . SSn are connected in series to constitute a switch set.
The switching node S1 and the switching node S2 of the first switch SS1 are connected in parallel to both terminals of the storage battery B1; the switching node S1 and the switching node S2 of the second switch SS2 are connected in parallel to both terminals of the storage battery B2; the switching node S1 and the switching node S2 of the nth switch SSn are connected in parallel to both terminals of the storage battery Bn; and so on.
An electricity storage component set is constituted of n−1 electricity storage components ST1, ST2, . . . STn-1 connected in series. Both terminals of the electricity storage component ST1 are connected in parallel to the common nodes C of the two switches SS1, SS2; both terminals of the electricity storage component ST2 are connected in parallel to the common nodes C of the two switches SS2, SS3; both terminals of the electricity storage component STn-1 are connected in parallel to the common nodes C of the two switches SSn-1 (not shown), SSn; and so on. The electricity storage component ST1, ST2, . . . STn-1 is a capacitor or a supercapacitor.
A pulse generator 14 controls the switching of the common node C of each switch SS1, SS2, SS3, . . . SSn between the switching node S1 and the switching node S2 at a frequency. The frequency of the pulse generator 14 for controlling each switch SS1, SS2, SS3, . . . SSn depends on the condition that the charging and discharging voltages of each storage battery B1, B2, B3, . . . Bn and electricity storage component ST1, ST2, . . . STn-1 connected in parallel are the same.
When the storage battery set (namely, the storage batteries B1, B2, B3, . . . Bn connected in series) supplies power to the load 12, the pulse generator 14 controls the conduction of the common node C of each switch SS1, SS2, SS3, . . . SSn and the switching node S1 at, for example, the positive cycle of a frequency, so that the storage battery B1 is connected in parallel to the electricity storage component ST1 through the common nodes C of the switches SS1, SS2 and the switching nodes S1, the storage battery B2 is connected in parallel to the electricity storage component ST2 through the common nodes C of the switches SS2, SS3 and the switching nodes S1, the storage battery Bn-1 is connected in parallel to the electricity storage component STn-1 through the common nodes C of the switches SSn-1 (not shown), SSn and the switching nodes S1, and so on; the pulse generator 14 controls the conduction of the common node C of each switch SS1, SS2, SS3, . . . SSn and the switching node S2 at the negative cycle of a frequency, so that the storage battery B2 is connected in parallel to the electricity storage component ST1 through the common nodes C of the switches SS1, SS2 and the switching nodes S2, the storage battery B3 is connected in parallel to the electricity storage component ST2 through the common nodes C of the switches SS2, SS3 and the switching nodes S2, the storage battery Bn is connected in parallel to the electricity storage component STn-1 through the common nodes C of the switches SSn-1 (not shown), SSn and the switching nodes S2, and so on.
Between the storage battery and the electricity storage component that are connected in parallel, the one having a higher voltage charges the other having a lower voltage, and inversely the latter discharges the former. For example, in the positive cycle of the first cycle, the storage battery B1 is connected in parallel to the electricity storage component ST1, and the storage battery B1 charges the electricity storage component ST1 so that the voltage of the electricity storage component ST1 equals to the voltage of the storage battery B1.
In the negative cycle of the first cycle, the storage battery B2 is connected in parallel to the electricity storage component ST1, and if the voltage of the storage battery B2 is higher than that of the electricity storage component ST1, the storage battery B2 charges the electricity storage component ST1 so that the voltage of the electricity storage component ST1 equals to the voltage of the storage battery B2.
In the positive cycle of the second cycle, the storage battery B1 is again connected in parallel to the electricity storage component ST1, and because the voltage of the storage battery B1 is lower than that of the electricity storage component ST1, the electricity storage component ST1 discharges to the storage battery B1 so that the voltage of the electricity storage component ST1 equals to the voltage of the storage battery B1.
In the negative cycle of the second cycle, the storage battery B2 is connected in parallel to the electricity storage component ST1, and because the voltage of the storage battery B2 is higher than that of the electricity storage component ST1, the storage battery B2 charges the electricity storage component ST1 again so that the voltage of the electricity storage component ST1 equals to the voltage of the storage battery B2.
As described above, the pulse generator 14 controls the switching of each switch SS1, SS2, SS3, . . . SSn, and the electricity storage components ST1, ST2, . . . STn-1 charge and discharge the adjacent storage batteries B1, B2, B3, . . . Bn. By means of the charge and discharge of energy until the voltage of each of the storage batteries B1, B2, B3, . . . Bn that are connected in series reaches consistency, the problem of unbalanced voltage between each of the storage batteries can be improved.
Each of m parallel switches SSP1, SSP2, . . . SSPm has a switching node S1, a switching node S2 and a common node C. The switching node S2 of the first parallel switch SSP1 and the switching node S1 of the second parallel switch SSP2 are electrically connected; the switching node S2 of the m−1th parallel switch SSPm-1 (not shown) and the switching node S1 of the mth parallel switch SSPm are electrically connected; and so on. These m parallel switches SSP1, SSP2, . . . SSPm are connected in series to constitute a parallel switch set.
The switching node S1 and switching node S2 of the first parallel switch SSP1 are connected in parallel to the two electricity storage components ST1, ST2 that are connected in series, the switching node S1 and switching node S2 of the second parallel switch SSP2 are connected in parallel to the two electricity storage components ST3, ST4 (not shown) that are connected in series, and so on. In another embodiment, the switching node S1 and switching node S2 of each parallel switch can be connected in parallel to more than two electricity storage components that are connected in series.
A parallel electricity storage component set is constituted of m−1 parallel electricity storage components STP1, . . . STPm-1 connected in series. Both terminals of the parallel electricity storage component STP1 are connected in parallel to the common nodes C of the two parallel switches SSP1, SSP2, both terminals of the parallel electricity storage component STPm-1 are connected in parallel to the common nodes C of the two parallel switches SSPm-1 (not shown), SSPm, and so on. The parallel electricity storage component STP1, . . . STPm-1 is a capacitor or a supercapacitor.
The pulse generator 24 controls the switching of the common node C of each parallel switch SSP1, SSP2, . . . SSPm between the switching node S1 and the switching node S2 at a second frequency. The second frequency of the pulse generator 24 for controlling each parallel switch SSP1, SSP2, . . . SSPm depends on the condition that the charging and discharging voltages of the two electricity storage components ST1, ST2 that are connected in parallel and the parallel electricity storage component STP1 are the same. The others can be deduced by analog and the description thereof is omitted. The first frequency of the pulse generator 24 is an integral multiple of the second frequency, and the pulse generator 24 divides the first frequency so as to obtain the second frequency.
For example, the pulse generator 24 controls the conduction of the common node C of each parallel switch SSP1, SSP2, . . . SSPm and the switching node S1 at the positive cycle of the second frequency, so that the two electricity storage components ST1, ST2 are connected in parallel to the parallel electricity storage component STP1 through the common nodes C of the parallel switches SSP1, SSP2 and the switching nodes S1. The others can be deduced by analog and the description thereof is omitted.
The pulse generator 24 controls the conduction of the common node C of each parallel switch SSP1, SSP2, . . . SSPm and the switching node S2 at the negative cycle of the second frequency, so that the two electricity storage components ST3, ST4 (not shown) are connected in parallel to the parallel electricity storage component STP1 through the common nodes C of the parallel switches SSP1, SSP2 and the switching nodes S2. The others can be deduced by analog and the description thereof is omitted.
Between the two serially-connected electricity storage components and the parallel electricity storage component that are connected in parallel, the one having a higher voltage charges the other having a lower voltage, and inversely the latter discharges the former.
For example, in the positive cycle of the first cycle, the two serially-connected electricity storage components ST1, ST2 are connected in parallel to the parallel electricity storage component STP1, and the two serially-connected electricity storage components ST1, ST2 charge the parallel electricity storage component STP1 so that the voltage of the parallel electricity storage component STP1 equals to the voltage of the two serially-connected electricity storage components ST1, ST2.
In the negative cycle of the first cycle, the two serially-connected electricity storage components ST3, ST4 (not shown) are connected in parallel to the parallel electricity storage component STP1, and if the voltage of the two serially-connected electricity storage components ST3, ST4 (not shown) is higher than that of the parallel electricity storage component STP1, the two serially-connected electricity storage components ST3, ST4 (not shown) charge the parallel electricity storage component STP1 so that the voltage of the parallel electricity storage component STP1 equals to the voltage of the two serially-connected electricity storage components ST3, ST4 (not shown).
In the positive cycle of the second cycle, the two serially-connected electricity storage components ST1, ST2 are again connected in parallel to the parallel electricity storage component STP1, and because the voltage of the two serially-connected electricity storage components ST1, ST2 is lower than that of the parallel electricity storage component STP1, the parallel electricity storage component STP1 discharges to the two serially-connected electricity storage components ST1, ST2 so that the voltage of the parallel electricity storage component STP1 equals to the voltage of the two serially-connected electricity storage components ST1, ST2.
In the negative cycle of the second cycle, the two serially-connected electricity storage components ST3, ST4 (not shown) are again connected in parallel to the parallel electricity storage component STP1, and because the voltage of the two serially-connected electricity storage components ST3, ST4 (not shown) is higher than that of the parallel electricity storage component STP1, the two serially-connected electricity storage components ST3, ST4 (not shown) charge the parallel electricity storage component STP1 again so that the voltage of the parallel electricity storage component STP1 equals to the voltage of the two serially-connected electricity storage components ST3, ST4 (not shown).
As described above, the pulse generator 24 controls the switching of each switch SS1, SS2, SS3, . . . SSn and parallel switch SSP1, SSP2, . . . SSPm, and the electricity storage components ST1, ST2, . . . STn-1 charge and discharge the adjacent storage batteries B1, B2, B3, . . . Bn, and the parallel electricity storage components STP1, . . . STPm-1 charge and discharge the adjacent two serially-connected electricity storage components ST1, ST2, . . . STn-1. For a larger amount of the storage batteries B1, B2, B3, . . . Bn, it takes a longer time to make the voltage of each storage battery B1, B2, B3, . . . Bn to reach consistency merely by the switch set (namely, the switches SS1, SS2, SS3, . . . SSn) and the electricity storage component set (namely, the electricity storage components ST1, ST2, . . . STn-1); however, with the parallel switch set (namely, the parallel switches SSP1, SSP2, . . . SSPm) and the parallel electricity storage component set (namely, the parallel electricity storage components STP1, . . . STPm-1) added into the charge and discharge balancing circuit, the further charge and discharge of energy will shorten the time that the voltage of each of the serially-connected storage batteries B1, B2, B3, . . . Bn reaches consistency, and the problem of unbalanced voltage between each of the storage batteries can be improved.
In another embodiment where the amount of the serially-connected storage batteries is increased, the amounts of parallel connections between the parallel switch sets and the parallel electricity storage component sets in the charge and discharge balancing circuit can be increased; namely, the first parallel switch set is connected in parallel to the electricity storage component set, the first parallel electricity storage component set is connected in parallel to the first parallel switch set, the second parallel switch set is connected in parallel to the first parallel electricity storage component set, the second parallel electricity storage component set is connected in parallel to the second parallel switch set, and so on. Thus the time that the voltage of each of the serially-connected storage batteries reaches consistency can be further shortened.
The present invention is advantageous in providing a charge and discharge balancing circuit for a storage battery set, which can make each storage battery achieve a balanced charge and discharge by a simple control of a switch set and the charge and discharge between the storage battery and the electricity storage component, thereby extending the cycle life of the storage battery set.
While the present invention has been described above with reference to the preferred embodiments and illustrative drawings, it should not be considered as limited thereby. Various equivalent alterations, omissions and modifications made to its configuration and the embodiments by the skilled persons could be conceived of without departing from the scope of the present invention.
Number | Date | Country | Kind |
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100124539 | Jul 2011 | TW | national |