Abstract:
A secondary cell featuring a transient rise in temperature once charged to saturation is coupled and thereby forms a composite structure with a charging assembly by mutual engagement of conductive contacts provided on either part. The force of union generated by the coupling compresses a thermosetting prestressed means which is a spring or other prestressed element the coupling brings the contacts into conduction to initiate charging. The stress is released once charging in the secondary cell reaches its saturation, followed by cutoff of the charging current to the secondary cell.

Description:
This application is a Continuation nonprovisional application Ser. No. 10/260/283 filed Oct. 1, 2002, now abandoned. 
    
    
     BACKGROUND OF THE INVENTION 
     Due to the booming development in hand-held or portable electric appliances or utilities, secondary rechargeable batteries or cells are finding ever more extensive applications from day to day. The present invention relates to a charging assembly and a secondary battery set, such as, for example, a nickel/cadmium, a nickel/hydrogen, a nickel/zinc, or a ferrous nickel cell, to be mounted in and matched with the charging assembly, the charging assembly and secondary battery set being furnished with conductive contacts to facilitate transfer of electric power from the charging assembly to the second battery set. The conductive contacts are arranged such that, once force is applied thereto in order to insert the secondary battery set into the charging assembly, a spring will be mechanically compressed to store stress, the spring being arranged to disengage the contacts when a transient temperature rises in response to charging saturation, i.e., after the contacts are brought into conduction to initiate a charging cycle, stress stored in the spring will be released by control of a temperature-responsive saturation testing device and an interface matched thereto. Cutoff of the secondary cell from the charging assembly may be made with respect only to the secondary battery cell, only to the charging assembly, or only to conductive contacts inside the charging assembly, so that charging current in the secondary cell is cut off altogether. The saturation testing device includes a temperature sensor arranged to test the rise in temperature when the cell charging reaches its saturation, and to thereby determine the timing to cut off charging once saturation is reached. Alternatively, a temperature testing means may be provided with conductive contacts in the charging assembly, so that the batter cell is secured in place when inserted into the charging assembly and a stable conduction is made between the entire charging assembly and the cell, so that charging may occur with respect to the cell, the temperature sensor being maintained in a set status until saturation occurs in the cell that is being charged, at which time the cell undergoes a rise in temperature and the temperature sensor responds by driving the charging assembly and the cell into a cutoff status in which the power supply to the secondary cell is cut off and charging current is blocked accordingly. 
     SUMMARY OF THE INVENTION 
     The present invention relates to the combination of a charging assembly and a secondary battery cell set characterized by a transient temperature rise when charged to saturation, both parts being furnished with conductive contacts to transfer power therebetween. The contacts are prestressed by the force applied to a spring when the conductive contacts are caused to engage and thereby brought into conduction so as to initiate a charging cycle. When the secondary cell reaches saturation, heat will intervene to release the prestressed state, causing the conductive contacts on both the secondary cell set and the charging assembly to be pushed apart, causing charging of the secondary cell to be cut off altogether. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  shows a first embodiment of the invention in which in which the temperature sensor is executed in the form of a thermo-resetting flip-flop metal spring interposed between the secondary cell and the charging assembly; 
         FIG. 2  is a circuit diagram for the embodiment of  FIG. 1 ; 
         FIG. 3  shows a second embodiment of the invention; 
         FIG. 4  is a circuit diagram for the embodiment of,  FIG. 3 ; 
         FIG. 5  shows a third embodiment of the invention in which the temperature sensor is executed in the form of a thermo-resetting flip-flop metal spring interposed between the secondary cell and the charging assembly; 
         FIG. 6  is a circuit diagram for the embodiment of  FIG. 5 ; 
         FIG. 7  shows a fourth embodiment of the invention; 
         FIG. 8  is a circuit diagram for the embodiment of  FIG. 7 ; 
         FIG. 9  shows a fifth embodiment of a invention in which the temperature sensor is executed in the form of a memory alloy or alternatively of a thermo-setting binary metal installed between the secondary cell and the charging assembly; 
         FIG. 10  shows a sixth embodiment of the invention in which the member in the form of a memory alloy or of a thermosetting binary metal, pursuant to the embodiment of  FIG. 9 , is installed in the secondary cell set instead; 
         FIG. 11  is a circuit diagram good for the embodiment of either  FIG. 9  or  FIG. 10 ; 
         FIG. 12  shows a seventh embodiment of the invention; 
         FIG. 13  shows an eighteen embodiment of the invention in which the memory alloy or thermosetting binary metal, pursuant to the embodiment of  FIG. 12  is installed in the secondary cell; 
         FIG. 14  is a circuit diagram for the embodiments of both FIG.  12  and FIG.  13 . 
         FIG. 15  shows a ninth embodiment of the invention in which the temperature sensor is executed in the form of a compression spring in conjunction with a thermosetting conductive contact made of a memory alloy or of a binary metal, installed between the secondary cell set and the charging assembly; 
         FIG. 16  is a circuit diagram for the embodiment of  FIG. 15 ; 
         FIG. 17  shows a tenth embodiment of the invention; 
         FIG. 18  is a circuit diagram for the embodiment of  FIG. 17 ; 
         FIG. 19  shows an eleventh embodiment of the invention in which the temperature sensor is executed in the form of a memory alloy or a thermosetting binary metal, installed between the secondary cell set and the charging assembly; 
         FIG. 20  shows a twelfth embodiment of the invention; 
         FIG. 21  shows a thirteenth embodiment of the invention that includes a combination of the block of a secondary cell set with a charging circuit featuring an open guided channel;  FIG. 22  illustrates the invention in a charging state which accounts for a fourteenth embodiment hereunder; 
         FIG. 23  shows a fourteenth embodiment of the invention in which a power supply is blocked by the disengagement of connection contacts between the secondary cell set and the charging assembly, including alternatively, disengagement of conductive contacts only of the secondary cell set, or of the charging assembly, or of contacts inside the charging assembly, occasioned by a charging saturation; 
         FIG. 24  illustrates a charging state of a fifteenth embodiment of the invention; 
         FIG. 25  illustrates the working of the fifteenth embodiment of the invention in which a power supply is blocked by the disengagement of connection contacts between the secondary cell set and the charging assembly, including alternatively, disengagement of conductive contacts only of the secondary cell set, of the charging assembly, or of contacts inside the charging assembly, occasioned by charging saturation; 
         FIG. 26  illustrates a sixteenth embodiment of the invention in a charging state; 
         FIG. 27  illustrates the working of the sixteenth embodiment of the invention in which a power supply is blocked by the disengagement of connection contacts between the secondary cell set and the charging assembly, including alternatively, disengagement of conductive contacts only of the secondary cell set, of the charging assembly, or of contacts inside the charging assembly, occasioned by charging saturation; 
         FIG. 28  shows a seventeenth embodiment of the invention seen in a charging state; 
         FIG. 29  illustrates the working of the seventeenth embodiment of the invention in which a power supply is blocked by the disengagement of connection contacts between the secondary cell set and the charging assembly, including alternatively, disengagement of conductive contacts only of the secondary cell set, of the charging assembly, or of contacts inside the charging assembly, occasioned by charging saturation; 
         FIG. 30  illustrates the charging state of an eighteenth embodiment of the invention; 
         FIG. 31  illustrates the working of the eighteenth embodiment of the invention in which a power supply is blocked by the disengagement of connection contacts between the secondary cell set and the charging assembly, including alternatively, disengagement of conductive contacts only of the secondary cell set, of the charging assembly, or of contacts inside the charging assembly, occasioned by charging saturation; 
         FIG. 32  illustrates a charging state of a nineteenth embodiment of the invention; 
         FIG. 33  illustrates the operation of the nineteenth embodiment of the invention in which a power supply is blocked by the disengagement of connection contacts between the secondary cell set and the charging assembly, including alternatively, disengagement of conductive contacts only of the secondary cell set, of the charging assembly, or of contacts inside the charging assembly, occasioned by charging saturation; 
         FIG. 34  illustrates a charging state of a twentieth embodiment of the invention; 
         FIG. 35  illustrates the operation of the twentieth embodiment of the invention in which a power supply is blocked by the disengagement of connection contacts between the secondary cell set and the charging assembly, including alternatively, disengagement of conductive contacts only of the secondary cell set, of the charging assembly, or of contacts inside the charging assembly, occasioned by charging saturation; 
         FIG. 36  illustrates a charging state of a twenty first embodiment of the invention; 
         FIG. 37  illustrates the twenty first embodiment of the invention in which power supply is blocked by the disengagement of connection contacts between the secondary cell set and the charging assembly, including alternatively, disengagement of conductive contacts only of the secondary cell set, or of the charging assembly, or of contacts inside the charging assembly, occasioned by a charging saturation; 
         FIG. 38  illustrates a charging state of a twenty second embodiment of the invention; 
         FIG. 39  illustrates the twenty second embodiment of the invention in which power supply is blocked by the disengagement of connection contacts between the secondary cell set and the charging assembly, including alternatively, disengagement of conductive contacts only of the secondary cell set, of the charging assembly, or of contacts inside the charging assembly, occasioned by charging saturation; 
         FIG. 40  illustrates a charging state of a twenty third embodiment of the invention; 
         FIG. 41  illustrates a twenty third embodiment of the invention in which power supply is blocked by the disengagement of connection contacts between the secondary cell set and the charging assembly, including alternatively, disengagement of conductive contacts only of the secondary cell set, of the charging assembly, or of contacts inside the charging assembly, occasioned by charging saturation; 
         FIG. 42  illustrates a charging state of a twenty fourth embodiment of the invention; and, 
         FIG. 43  illustrates a twenty fourth embodiment of the invention in which a power supply is blocked by the disengagement of connection contacts between the secondary cell set and the charging assembly, including alternatively, disengagement of conductive contacts only of the secondary cell set, of the charging assembly, or of contacts inside the charging assembly, occasioned by charging saturation. 
     
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     As covered by the present invention, the cell charging saturation testing device can include any of a variety of temperature sensors, with the charging assembly and the secondary battery cell set being couple in a vertically upwards direction and uncoupled downwards, or alternatively coupled downwardly and uncoupled upwardly in a vertical direction; or coupled and uncoupled horizontally; or coupled and uncoupled in an angular setting relative to each other, and in which the prestressed thermosetting means comprises any of the following:
         1. Thermosetting flip-flop binary metal spring sheets;   2. A thermosetting flip-flop binary metal retainer and spring;   3. A resilient positioning mortise joint and dovetail coupling provided on both the charging assembly and the secondary battery cell set to localize charging operation, and complemented with a thermo-setting memory alloy or binary metal structure to be deformed by heat expression once charging taking place in the secondary cell set has reached its saturation, at which time conductive contacts binding the secondary cell set with the charging assembly are brought apart, including alternatively disengaging contacts solely in the secondary cell set, solely in the charging assembly, or within the charging assembly, so that the power supply is blocked forthwith;   4. Conductive contacts on the charging assembly and conductive contacts on the secondary cell set retained resiliently in position with respect to each other, forming thereby a pair, and having thermosetting memory alloy or binary metal sheets, or annular spring units arranged on the secondary cell set once the cell set is loaded in place, so that a secured attachment is made, and so that thermal deformation which occurs when the secondary cell set is charged to saturation will bring the secondary cell set and the charging assembly apart from each other by disengagement of the pair of contacts in the secondary cell set, in the charging assembly, or within the charging assembly, so that the power supply is blocked forthwith;   5. A thermosetting memory alloy or binary metal processed into conductive contacts for the charging assembly, which, in addition to getting coupled to conductive contacts on for coupling to the secondary cell set, also hold the secondary cell set in position so that, on being heated by saturation of the secondary cell set, will deform to release hold of the secondary cell set, causing the secondary cell set to fall straight off the conductive contacts of the charging assembly and thereby cut-off the power supply;   6. Shape memory alloy or binary metal contacts transformed by heat, together with another set of contacts functioning as a prestress spring coupled to the conductive contacts on the secondary cell set, to hold in place the secondary cell so that when the conductive contacts on the charging assembly receive heat from the effect of saturation of the secondary cell set, they become deformed to release hold of the secondary cell set, the interactive coupling of contacts between the secondary cell set and the charging assembly being released by the prestressed conductive contact functioning like a prestressed spring, or alternatively released to cut-off the power supply by prestressed spring action with respect to the secondary cell set only, the charging assembly only, or internal contacts of the charging assembly only, it is to be understood that both sets of conductive contacts of the charging assembly may feature thermosetting or prestressed spring traits.       

     Structured accordingly, when the secondary cell is loaded into the charging assembly, force applied externally will compel the cell to bring contacts on both the charging assembly and the cell into conductive coupling, whereupon charging to the cell begins, which in turn brings the Battery Charging Saturation Testing Device to a testing state. Once the cell is charged to saturation, then both the Charging Saturation Testing Device and the interfacing matched thereby will respond to reset both the charging assembly and the cell set to a released, that is, open state, and power supply to the secondary cell set is blocked forthwith. 
     A first embodiment of the invention in which the temperature sensor is in the form of a thermo-resetting flip-flop binary metal spring interposed between the secondary cell set and the charging assembly is illustrated in FIG.  1 . When the secondary cell set H 102  and the charging assembly H 101  are coupled together, the force of union occasioned thereby will compel the thermo-resetting flip-flop binary metal spring TH 201  to revert to a pre-stressed state so that contacts P 102 , P 106  on the secondary cell set H 102  and contacts P 101 , P 105  on the charging assembly H 101  are brought into conductive engagement, thereby enabling the charging power from the charging assembly H 101  to charge the secondary cell set H 102 . When charging of the secondary cell B 101  reaches its saturation, accompanied by a rising of temperature to a predetermined level, the thermo-resetting flip-flop, i.e., bistable, binary metal spring TH 201  interposed between the secondary cell set H 102  and the charging assembly H 101  will reset thermally to release its stored prestress, thus disengaging corresponding contacts on the secondary cell set and on the charging assembly. The action of binary metal spring TH 201  may of course be arranged to only affect the contacts on the secondary cell set, on the charging assembly, or within the charging assembly. Charging current to the secondary cell B 101  is thereby cut off. This embodiment comprises essentially:
         Charging assembly H 101 , in plane or dovetail coupling with the secondary cell set H 102 , and including a built-in D.C. power supply circuit and conductive contacts P 101 , P 105  for coupling with counterparts P 102  and P 106  on the secondary cell;   A D.C. power supply made up of a D.C. system or one converted from an A.C. system through rectification, and serving to charge the secondary cell by way of a charging circuit;   Secondary cell set H 102 , enclosed in an insulation casing and incorporating a secondary cell B 101  and conductive contacts P 102 , P 106  in line with the positive/negative terminals of-the secondary cell B 101 ; the interface between the secondary cell H 102  and the charging assembly H 101  being provided with a thermo-resetting flip-flop binary metal spring TH 201 ;   Thermo-resetting binary flip-flop metal spring TH 201  comprising one or more pieces superposed in a same or opposite functional direction and interposed at the interface between the charging assembly H 101  and the secondary cell set H 102  to convert the force applied on both when combined into stored stress to be released whenever the thermo-resetting flip-flop binary metal spring TH 201  resets itself due to heat resulting from a rise in temperature due to charging of the secondary cell B 101  to saturation, at which point corresponding contacts on both the secondary cell set and on the charging assembly are released.       

     A circuit diagram for the example illustrated in  FIG. 1  is given in  FIG. 2 , wherein the power to charge the secondary cell set is D.C. by way of the conductive contacts common on both the charging assembly and the secondary cell set. 
     A second embodiment of the invention is illustrated in  FIG. 3 , which is in fact a modification of the embodiment of FIG.  1 . In this embodiment, an auxiliary contact P 100  is added to the charging assembly H 101 , to release the prestress stored in the thermo-resetting flip-flop binary metal spring TH 201  when it is reset by the heat which results from a rise in temperature as charging of the secondary cell B 101  reaches saturation, so as to release the coupling of contacts on both the secondary cell set and the charging assembly so that charging current to the secondary cell B 101  is blocked forthwith even though conduction is still maintained way between the contacts P 101  on the charging assembly H 101  and contacts P 102  on the secondary cell set H 102 . As a result of the addition of an auxiliary contact P 100  which is in series with a current limiting resistor R 101  with the power supply, conduction is made with the contact P 106  on the secondary cell set H 102 , thereby maintaining a small charging current from the power supply to the secondary cell. 
     A circuit diagram of the embodiment of  FIG. 3  is given in FIG.  4 .
         third embodiment of the invention in which the temperature sensor is executed in the form of a thermo-resetting binary flip-flop metal spring between the secondary cell and the charging assembly is illustrated in FIG.  5 . When the secondary cell set H 102  and the charging assembly H 101  are coupled together, the force of union occasioned thereby will compel the thermo-resetting flip-flop binary metal spring TH 201  to revert to a pre-stressed state so that contacts P 102 , P 016  on the secondary cell set H 102  and contacts P 101 , P 105  on the charging assembly H 101  are brought conductively altogether, thereby enabling the charging power from the charging assembly H 101  to charge the secondary cell set H 102 . When charging of the secondary cell B 101  reaches saturation due to a rise in temperature to a predetermined level, the thermo-resetting flip-flop binary metal spring TH 201  interposed between the secondary cell set and the charging assembly H 101  will reset thermally to release its stored prestress, thus disengaging corresponding contacts on the secondary cell set and on the charging assembly and thereby blocking charging current to the secondary cell B 101 . This embodiment comprises essentially the same elements as described in connection with  FIG. 1 , except that the binary metal spring TH 201  is installed in the secondary cell set H 102 .       

     A circuit diagram for the embodiment of  FIG. 5  is given in FIG.  6 . 
     A fourth embodiment of the invention is illustrated in  FIG. 7 , which is in fact a modification of the embodiment of FIG.  5 . This embodiment is distinguished by the addition of an auxiliary conductive contact P 100 , corresponding to the auxiliary conductive contact shown in  FIG. 3 , to the charging assembly H 101 , to release the prestress stored in the thermo-resetting flip-flop binary metal spring TH 201  when it is reset by the heat which results from a rise in temperature as charging of the secondary cell B 101  reaches saturation, so as to release the coupling of contacts on both the secondary cell set and the charging assembly so that the main charging current to the secondary cell B 101  is blocked forthwith while still maintaining conduction between the contacts P 101  on the charging assembly H 101  and the contacts P 102  on the secondary cell set H 102 . By the addition of auxiliary contact P 100  which is in series with a current limiting resistor R 101  with the power supply, conduction is made with the contact P 106  on the secondary cell set H 102 , thereby maintaining a small charging current as from the power supply to the secondary cell. 
     A circuit diagram for the embodiment of  FIG. 7  is given in FIG.  8 . 
     A fifth embodiment of the invention in which the temperature sensor is executed in the form of a memory alloy or binary metal base thermosetting structure interposed between the secondary cell set and the charging assembly, is illustrated in  FIG. 9 , with the secondary cell set H 102  comprising at least one elastic positioning tenon L 100  to be matched with counterpart coulisse S 300  provided on the charging assembly H 101 . The tenon L 100  and coulisse S 300  are have complementary structures so that when the secondary cell H 102  is combined with the charging assembly H 101 , both are coupled in conduction by the engagement realized between the elastic positioning tenon L 100  and the coulisse or mortise S 300 , thereby putting contacts P 102 , P 106  on the secondary cell H 102  into conductive coupling with contacts P 101 , P 105  on the charging assembly H 101 . As a result, charging power from the charging assembly H 101  will charge the secondary cell B 101  in the secondary cell set H 102 , and by the force of union, the memory alloy or binary metal base thermosetting structure TH 501  will be compressed such that once the secondary cell B 101  is charged to saturation, increasing the temperature to a predetermined level, the thermosetting structure TH 501  composed of a memory alloy or binary metal lying between the secondary cell H 102  and the charging assembly H 101  will be deformed, releasing the contact-to-contact coupling between the secondary cell H 102  and the charging assembly H 101 , and further, disengaging the elastic positioning tenon on the secondary cell H 102  from the mortise on the charging assembly H 101  so that charging current to the secondary cell B 101  is cut off forthwith. This embodiment essentially comprises:
         Charging assembly H 101  in plane or dovetail coupling with the secondary cell set H 102 , and equipped with D.C. power supply and contacts P 101 , P 105  for coupling with the secondary cell set H 102 ;   A D.C. power supply or source of D.C. power converted through rectification from an A.C. source, and serving to charge the secondary cell by way of a charging circuit;   Secondary cell set H 102  enclosed in an insulation casing and equipped with a secondary cell B 101  and contacts P 102 , P 106  meant for coupling with the positive/negative terminals of the secondary cell B 101 , the interface between the secondary cell set H 102  and the charging assembly H 101  being equipped with a memory alloy or binary metal base thermosetting structure TH 501 ;   At least one elastic positioning tenon L 100  equipped on the secondary cell H 102 , and a corresponding mortise S 300  provided on the charging assembly H 101 , thereby forming a pair which may have complementary structures;   One or more alloy or binary metal base thermosetting structures TH 501  between the coupling front of both the charging assembly H 101  and the secondary cell H 102 , so that compression is received when both are combined together, and so that when there is a rise in temperature due to saturation of the secondary cell B 101 , the memory alloy or binary metal base thermosetting structure (s) TH 501  will be affected by the heat produced thereby and expand to cause coupling of the elastic tenon with the mortise, releasing the coupling of the secondary cell H 102  with the charging assembly H 101 , and undoing the contact-to-contact coupling between the secondary cell and the charging assembly, cutting-off charging current to the secondary cell B 101 . Those skilled in the art will appreciate that the memory alloy or binary metal base thermosetting structure TH 501  maybe equipped on the charging assembly H 101  or alternatively, where justified, on the secondary cell H 102 .       

     A sixth embodiment of the invention in which the memory alloy or binary metal base thermosetting structure according to the embodiment of  FIG. 9  is installed on the secondary cell set illustrated in FIG.  10 . 
     A circuit diagram illustrative of both examples given in the illustration of  FIGS. 9 and 10 , is given in FIG.  11 . 
     A seventh example of the invention is illustrated in  FIG. 12 , which is in fact a modification of the example shown in  FIG. 9  by the addition of an auxiliary conductive contact P 100  to the charging assembly H 101 , so that once a rise in temperature is occasioned by the charging of the secondary cell B 101  to saturation, the memory alloy or binary metal base thermosetting structure TH 501  resets itself due to the heat produced thereby, releasing the contact-to-contact coupling between the secondary cell and the charging assembly, and cutting-off the charging current to the secondary cell B 101 , at which time contact P 101  on the charging assembly H 101  is still is still in electrical contact with contacts P 102  on the secondary cell H 102 . As a result of the provision of an auxiliary contact P 100  which is in series with power supply by the intervention of a current limiting resistor R 101 , conductive contact P 106  on the secondary cell H 102  is made conductive so that an ongoing small current is maintained from power supply to the secondary cell B 101 . 
     An eighth example of the invention is shown in  FIG. 13  which is a variant of the example shown in  FIG. 12 , in which the memory alloy or binary metal base thermosetting structure is installed in the secondary cell set instead. 
     A circuit diagram illustrative of both examples covered in  FIG. 12 ,  FIG. 13 , is given in FIG.  14 . 
       FIG. 15  illustrates a ninth example of the invention in which a compression spring is interposed between the secondary cell and the charging assembly, and the temperature sensor is executed in the form of a memory alloy or binary metal base thermosetting contact structure, with the provision of conductive contacts P 311 , P 312  having mortise thereon on the secondary cell set H 102 , on the one hand, and provision of counterpart thermosetting conductive contacts THP 101 , THP 102 , made of memory alloy or binary metal, on the charging assembly. On the other hand, both parts may be reciprocally replaceable. When the secondary cell set H 102  and the charging assembly H 101  are combined together, said pair of conductive contacts will be engaged elastically in conduction. The force of union occasioned thereupon compressing the compressible piece of or annular spring SP 103 . Once charging in the secondary cell B 101  reaches its saturation such that the rise in temperature occasioned thereby comes to a predetermined level, the heat produced in the meantime will deform the memory alloy or binary metal base thermosetting contacts THP 101 , THP 102  located in the charging assembly H 101 . The structure will then get rid of coupling between corresponding contacts on the secondary cell H 102 , cutting-off charging current to the secondary cell B 101  concurrent with release of the prestress stored in the compression spring SP 103  to disengage the contact-to-contact coupling between the secondary cell and the charging assembly. This embodiment comprises essentially:
         Charging assembly H 101  in plane or dovetail coupling with the secondary cell set H 102 , and comprising a D.C. power supply and memory alloy or binary metal base thermosetting contacts P 101 , P 105  meant for coupling with counterpart contacts on the secondary cell set H 102 ;   A D.C. power supply for supplying D.C. power and/or for converting, through rectification, power from an A.C. soruce, to charge the secondary cell set by way of a charging circuit;   Secondary cell set H 102  enclosed in an insulation casing, and equipped with secondary cell B 101  and contacts P 312 , P 311  for coupling with positive/negative terminals of the secondary cell B 101 , the interface between the secondary cell set H 102  and the charging assembly H 101  being equipped with a compressible piece or annular spring, contacts P 311 , P 312  including a positioning mortise thereon, and the charging assembly H 101  being equipped with a memory alloy or binary metal base thermosetting contacts THP 101 , THP 102  which are reciprocally replaceable, and compressible piece or annular spring SP 103  being interposed between the coupling interface of the charging assembly H 101  and the secondary cell set H 102 , such that when both are coupled the compression produced thereby will leave its effect upon spring SP 103 , and when charging in the secondary cell B 101  reaches its saturation to incur a rise in temperature accompanied with heat produced thereby to deform the memory alloy or binary metal base thermosetting contacts THP 101 , THP 102 , the contact-to-contact coupling between the secondary cell set H 102  and the charging assembly H 101  will be broken concurrent with cutoff of charging current to the secondary cell B 101 , the compression spring SP 103  being released at the same time to break the contact-to-contact coupling between the secondary cell set and the charging assembly.       
     A circuit diagram descriptive of the embodiment of  FIG. 15  is given in FIG.  16 . 
     A tenth embodiment of the invention is illustrated in  FIG. 17 , which is in fact a modification of the embodiment shown in  FIG. 15  by the addition of an auxiliary conductive contact P 100  to the charging assembly H 101 . Once a rise in temperature is occasioned by the charging of the secondary cell B 101  to its saturation, such that the memory alloy or binary metal base thermosetting contacts THP 101 , THP 102  relax themselves due to the heat produced thereby, the contact-to-contact coupling between the secondary cell and the charging assembly will be broken, including (as in the other embodiments of the invention) alternatively disengaging contacts on the secondary cell set only, of contacts on or within the charging assembly only, and the charging current to the secondary cell B 101  is cut off forthwith, at which time contact THP 101  on the charging assembly H 101  is still maintained conductive with contact P 311  on the secondary cell set H 102 , so that by the provision of the auxiliary contact P 100  in series with a current limiting resistor R 101  in line with power supply, conduction is made with contact P 312  on the secondary cell set H 102 , making possible the maintenance of an ongoing, small current charged by the power supply to the secondary cell B 101 . 
     A circuit diagram descriptive of the embodiments of  FIG. 17  is given in FIG.  18 . 
     An eleventh example of the invention in which the temperature sensor is executed in the form of a memory alloy or binary metal base thermosetting structure interposed way between the secondary cell and the charging assembly is illustrated in  FIG. 19 , featuring the provision of a trigger switch LS 101  opposite the charging assembly H 101 , for control of the input side or output side of the power supply. When the secondary cell set H 102  and the charging assembly H 101  are combined, contacts P 102 , P 106  on the secondary cell set H 102  form a conducting pair with contacts P 101 , P 105  on the charging assembly H 101 . In the meantime, the trigger switch LS 101  in control of the power supply for charging purposes is enabled to bring the power supply to the charging assembly H 101  for charging of the secondary cell B 101  in the secondary cell set H 102 . Again, the force of union incurred thereupon will compress, in the meantime, the memory alloy or binary metal base thermosetting structure TH 501 , so that when the secondary cell B 101  is charged to saturation, a driving power will be created to drive an auxiliary heater HT 101 , whereby heat is produced to deform the memory alloy or binary metal base thermosetting structure TH 501  interposed between the secondary cell set H 102  and the charging assembly H 101 , with the result that the contact-to-contact coupling between the secondary cell set and the charging assembly is broken, including, as in all of the above-described embodiments, alternatively disengaging contacts on the secondary cell set only, or contacts on or within the charging assembly only, concurrent with switching off of the trigger switch LS 101  that controls the power supply and is in charge of the charging operation between the secondary cell set H 102  and the charging assembly H 101 , followed by cutoff of the charging current to the secondary cell B 101 . This embodiment comprises essentially:
         Charging assembly H 101  in plane or dovetail coupling with the secondary cell set H 102 , and furnished with D.C. power supply and contacts P 101 , P 105  for coupling with the secondary cell set H 102 , as well as trigger switch LS 101 , which controls the power supply for charging purposes by switching on or off the input or output of the power supply;   A D.C. power supply as described above;   Secondary cell set H 102  enclosed in an insulation casing and incorporating a secondary cell B 101  and contacts P 102 , P 106  in line with positive/negative terminals of the secondary cell B 101 ; the coupling interface of the secondary cell set H 102  and the charging assembly H 101  being interposed with a memory alloy or binary metal base thermosetting structure TH 501 ;   A conventional emplacement for charging stability interposed between the secondary cell set H 102  and the charging assembly H 101 ;   Memory alloy or binary metal base thermosetting structure TH 501  provided singly or plurally and interposed between the interface of the charging assembly H 101  and the secondary cell set H 102  and compressed tightly when both are combined together to drive, by the heat produced when charging in the secondary cell B 101  reaches its saturation, the auxiliary electric heater HT 101 , which in turn results in an expansion of the memory alloy or binary metal base thermosetting structure TH 501  breaking of the contact-to-contact coupling between the secondary cell set and the charging assembly, including alternatively disengaging contacts on the secondary cell set alone or contacts on or within the charging assembly alone, such that the trigger switch LS 101  controlling the power supply is driven open, and charging current to the secondary cell B 101  is cut off forthwith.       

     A twelfth embodiment of the invention is illustrated in  FIG. 20 , which is in fact a modification of the embodiment shown in  FIG. 19  by the addition of an auxiliary conductive contact P 100  to the charging assembly H 101 . When charging in the secondary cell B 101  reaches its saturation, heat produced thereby is invested in the form of electric power, which in turn drives the auxiliary electric heater HT 101  to yield thermal energy sufficient to reset the memory alloy or binary metal base thermosetting structure TH 501 , breaking the contact-to-contact coupling between the secondary cell set and the charging assembly, the cutting off charging current to the secondary cell B 101 , at which time charging assembly H 101 , through its contact P 101  and the secondary cell set H 102  through its contact P 102  are maintained mutually conductive all the same, while the auxiliary contact P 100  in series with the power supply by way of a current limiting resistor R 101  maintains electrical contact with contact P 106  on the secondary cell B 101 , such that a small but ongoing current is maintained from the power supply to the secondary cell B 101  for charging purposes. 
     In any of the examples numbered 1 through 12 disclosed hereinbefore, coupling of the charging assembly H 101  with the secondary cell set H 102  may be executed vertically, and breaking of the coupling may be carried out in a downwards direction as opposed to coupling which is done upwardly; or alternatively the coupling may be executed in a downwards direction, and breaking of the coupling may be carried out upwardly; or the coupling may be executed horizontally, and disengagement likewise horizontally; and indeed coupling and disengagement may be designed and executed at other angles, as preferred in any specific application. 
     In  FIG. 21  is shown a thirteenth embodiment of the invention, in which the secondary cell set is executed in a block to be coupled with the charging assembly by engaging into a chute channel provided for the purpose. This embodiment comprises:
         A charging assembly H 101  to be coupled with the secondary cell set vertically upwardly, and disengaged therefrom downwardly; or alternatively to be coupled downwardly and disengaged upwardly; or coupled and disengaged horizontally; or else coupled and disengaged at other chosen angular settings; and on which is provided a chute channel to accommodate the secondary cell set H 102 ; the charging assembly further being furnished with a D.C. power supply and contacts P 801 , P 805  as well as permanent magnet PM 300 , and memory alloy or binary metal base thermosetting structure TH 501  or alternatively a helicoidal spring TH 601  of the same base and to the same purpose, and the secondary cell set H 102  being equipped with contacts P 802 , P 806  for coupling with the secondary cell B 101  and magnet core F 102 , such that when the charging assembly H 101  and the secondary cell set H 102  are combined, mutual attraction between the magnet core F 102  on the secondary cell set H 102  and the permanent magnet PM 300  on the charging assembly will compress the memory alloy or binary metal base thermosetting structure TG 501 , or compress a helicoidal spring TG 601  subject to thermally induced deformation, thereby setting contacts P 801 , P 805  on the charging assembly into conduction with contacts P 802 , P 806  on the secondary cell set, followed by charging with respect to the secondary cell B 101 , whereby since the secondary cell set is equipped with thermo-transmission block TC 101  which is coupled to the memory alloy or binary metal base thermosetting structure TH 501  on the charging assembly, when charging in the secondary cell reaches its saturation concurrent with the release of heat, the memory alloy or binary metal base thermosetting structure TH 501  will generate a pushing force in the wake of such heat that is sufficient to disengage both the magnet core F 102  and the permanent magnet PM 300 , coacting contact pairs on both the secondary cell set and on the charging assembly being thereby broken and charging current to the secondary cell B 101  cut off forthwith.       

     This model of charging device features the storage of prestress by maximization of the force of union and the release of the same prestress through thermal actuation to achieve cutting-off of the power supply, and incorporates furthermore a secondary cell charging means of which both positive/negative terminals are meant to be accessed to axial receptacles on specific applications, such that in the wake of a rise in temperature occasioned by charging of the secondary cell to its saturation, the secondary cell set will get rid of the charging electrode, resulting in cutoff of charging current. This embodiment comprises essentially:
         A reciprocal, resilient pair of retention couplings formed by contacts P 500 , P 401  on the charging assembly H 101  and contacts P 500 , P 501  on the secondary cell set H 102 , and a memory alloy or binary metal base thermosetting structure TH 801  executed as a metal sheet or helicoidal spring positioned under the secondary cell set, which cell set H 102  remains steady and stable when loaded with a secondary cell B 101  therein, the thermosetting structure TH 801  being deformed thermally when the secondary cell set H 102  is charged to saturation by an amount sufficient to break the contact-to-contact coupling between the secondary cell set and the charging assembly.       

       FIG. 22  is an illustration of the invention in a charging state which accounts for a fourteenth embodiment hereunder; 
       FIG. 23  is an illustration of a fourteenth embodiment of the invention in which the power supply is blocked by the disengagement of contacts between the secondary cell set and the charging assembly, including alternatively, disengagement of conductive contacts only of the secondary cell set, or only on or within the charging assembly, occasioned by a round of charging saturation; 
       FIGS. 24 and 25  respectively illustrate a fifteenth embodiment of the invention in which the power supply is first in a charging state then blocked by the disengagement of contacts between the secondary cell set and the charging assembly, including alternatively, disengagement of contacts only of the secondary cell set, or on or within the charging assembly only, occasioned by a charging saturation; 
       FIG. 26  illustrates a sixteenth embodiment of the invention in a charging state and  FIG. 27  illustrates the sixteenth embodiment of the invention in a state in which the power supply is blocked by the disengagement of contacts between the secondary cell set and the charging assembly, including alternatively, disengagement of contacts only of the secondary cell set, or only on or within the charging assembly, occasioned by a charging saturation; 
       FIG. 28  illustrates a seventeenth embodiment of the invention seen in a charging state and  FIG. 29  illustrates the operation of the seventeenth embodiment of the invention, in which the power supply is blocked by the disengagement of contacts between the secondary cell set and the charging assembly, including alternatively, disengagement of contacts only of the secondary cell set, or only on or within the charging assembly, occasioned by charging saturation.
         In the embodiments illustrated in  FIGS. 30-33 , contacts P 402 , P 403  serve as conduction points for the memory alloy or binary metal base thermosetting structure, upon coupling with counterpart contacts P 500 , P 501  on the secondary cell set H 102 , and also to store and exhibit resilient retention for holding the secondary cell set H 102 . When compressible spring SP 104 , executed as a plate of helical spring integral with the secondary cell B 101 , is loaded into the secondary cell set H 102 , thereby providing a compression means, the contacts P 402 , P 403 , will become deformed by the heat released once charging in the secondary cell reaches its saturation, at which time the secondary cell set H 102  is released, and the compression spring SP 104  will break the contact-to-contact coupling between the secondary cell and the charging assembly, including alternatively disengaging contacts only of the secondary cell set, or on or within the charging assembly, so that charging is terminated forthwith, as explained below:       
       FIG. 30  illustrates an eighteenth embodiment of the invention; and  FIG. 31  illustrates the working of the eighteenth embodiment of the invention, in which the power supply is blocked by the disengagement of contacts between the secondary cell set and the charging assembly, including alternatively, disengagement of contacts only of the secondary cell set, or only of or within the charging assembly, occasioned by charging saturation; 
       FIG. 32  illustrates a charging state of a nineteenth embodiment of the invention; and  FIG. 33  illustrates the working of a nineteenth embodiment of the invention, in which the power supply is blocked by the disengagement of contacts between the secondary cell set and the charging assembly, including alternatively, disengagement of contacts only of the secondary cell set, or of or within the charging assembly only, occasioned by charging saturation; 
       FIG. 34  illustrates a charging state of a twentieth embodiment of the invention; and  FIG. 35  illustrates the working of the twentieth embodiment of the invention, in which the power supply is blocked by disengagement of contacts between the secondary cell set and the charging assembly, including alternatively, disengagement of contacts only of the secondary cell set, or of or within the charging assembly, occasioned by a charging saturation; 
       FIG. 36  illustrates a charging state of a twenty first embodiment of the invention; and  FIG. 37  illustrates a twenty first embodiment of the invention, in which power supply is blocked by the disengagement of contacts between the secondary cell set and the charging assembly, including alternatively, disengagement of contacts only of the secondary cell set, or of or within the charging assembly only, occasioned by charging saturation.
         As a result of the contacts P 405  being furnished on the memory alloy or binary metal base thermosetting charging assembly H 101 , and another set of contacts PSP 406  featuring a prestressed spring function, extended with an insulated stretch arm A 100 , when a secondary cell set is loaded, coupling will be made with respect to contacts P 500 , P 501  on the secondary cell set H 102 , which, together with the secondary cell set H 102  being clamped in the meantime, will start charging with respect to the secondary cell set, whereupon the engaging head AT 100  on the tail end of the insulated stretch arm A 100  is matched with counterpart engaging receptacle BT 100  on the tail end of the memory alloy base in a prestressed engagement. When charging in the secondary cell set H 102  reaches saturation to release heat, contact P 405  on the charging assembly H 101 , on receiving said heat, will be deformed, resulting in dissociation of the insulated stretch arm A 100  on the contact PSP 406  that is retained by prestress, apart from the engaging receptacle BT 100 , such that the secondary cell set H 102  is released, after which the prestress stored in the insulated stretch arm A 100  on the contact PSP 406  enabled by said prestress will break the contact-to-contact coupling thus far established between the secondary cell set and the charging assembly, alternatively through disengagement of contacts on the secondary cell set only, contacts on or within the charging assembly only, or both, and power supply for charging purposes cut off forthwith. As an alternative structure the two sets of contacts on the charging assembly H 101  may comprise entirely prestressed thermosetting, spring-functioning contacts with extension of an insulated stretch arm, in respect of which several embodiments include those given in:       
       FIG. 38 , which illustrates a charging state of a twenty second embodiment of the invention; and  FIG. 39 , which illustrates the twenty second embodiment of the invention, in which the power supply is blocked by the disengagement of contacts between the secondary cell set and the charging assembly, including alternatively, disengagement of contacts only of the secondary cell set, or of or within the charging assembly only, occasioned by charging saturation; 
       FIG. 40 , which illustrates a charging state of a twenty third embodiment of the invention; and  FIG. 41 , which illustrates the twenty third embodiment of the invention, in which the power supply is blocked by the disengagement of contacts between the secondary cell set and the charging assembly, including alternatively, disengagement of contacts only of the secondary cell set, or of or within the charging assembly only, occasioned by charging saturation.
         Contacts P 407 , P 408  on the memory alloy or binary metal base thermosetting charging assembly H 101 , serve not only to be coupled to contacts P 500 , P 501  on the secondary cell set H 102 , but also to hold the secondary cell set H 102  in place as well. When the secondary cell set H 102  is charged to saturation followed by release of heat, contacts P 407 , P 408  on the charging assembly H 101 , receiving the heat, will release hold of the secondary cell set H 102 , so that the secondary cell set H 102  will drop forthright clear of contacts P 407 , P 408 , and the charging capability is blocked forthwith, as follows:       
       FIG. 42  illustrates a charging state of a twenty fourth embodiment of the invention; and  FIG. 43  illustrates the twenty fourth embodiment of the invention, in which the power supply is blocked by the disengagement of contacts between the secondary cell set and the charging assembly, including alternatively disengagement of contacts only of the secondary cell set, or only of or within the charging assembly, occasioned by charging saturation. 
     Since in applications a variety of structures for the execution of thermosetting temperature sensor for the determination of charging saturation occurring with a secondary cell are available, with a view to promote safety in operation, a specific execution may be chosen for the making of a charging assembly featuring reservation of prestress which is to be released to cut off power supply in the wake of heat discharged when charging reaches its saturation, or preferably two or multiple thermosetting temperature sensors may be installed to further enhance the safety feature. In fact, the conventional type of automatic power cutoff models may be combined for use in preferred applications which include but are not limited to those cited below:
         1. Those provided with an auxiliary heater which will produce heat when receiving electric power incurred by saturation of charging in the secondary cell set, the auxiliary heater being of a flip-flop binary metal prestressed design or of a thermosetting binary metal design, heat thus produced breaking the contact-to-contact coupling between the secondary cell set and the charging assembly, including alternatively disengaging contacts on the secondary cell set only or of or within the charging assembly only, so that power supply is cut off forthwith; or   2. Those provided with a bistable metal prestressed spring or memory alloy or binary metal base thermosetting structures which, when receiving heat that is produced as charging in the secondary cell reaches saturation, will break the contact-to-contact coupling between the secondary cell set and the charging assembly, including alternatively, disengaging contacts on the secondary cell only, or disengaging contacts on or within the charging assembly, such that power supply is cut off forthwith; or   3. Those provided with a resilient positioning means comprising a memory alloy or binary metal base thermosetting structure which, together with a compression spring seated between the charging assembly and the secondary cell set, will, by releasing the spring due to triggering effect when the thermosetting resets itself in the wake of effectual heat, break the connection to the secondary cell and cut off the power supply forthwith; or   4. Those provided with a resilient positioning means which is bound by conductive contacts and made from a memory alloy or binary metal base thermosetting structure which, when receiving an effectual heat, will trigger a prestressed spring that is seated way between the charging assembly and the secondary cell set, so that the secondary charging cell is disengaged and the charging power supply is cut off forthwith; or   5. Those on which the memory alloy or binary metal base thermosetting structure is executed to be a charging assembly with conductive contacts thereon furnished to accommodate coupling with counterpart contacts on the secondary cell set, and in the mean time to hold the same secondary cell set in place, such that the contacts on the charging assembly, when affected by the heat released from the secondary cell as it is charged to saturation, will get deformed, thereby releasing the secondary cell set which will then drop off the contacts, causing charging to be cut off forthwith;   6. Those structured such that, due to contacts furnished on the memory alloy or binary metal base thermosetting charging assembly, as well as another set of contacts featuring a prestressed spring function, extended with an insulted stretch arm, will establish a coupling and start charging when a secondary cell set is loaded, whereupon the engaging head on the tail end of the insulated stretch arm is matched with counterpart engaging receptacle on the tail end of the memory alloy base. When charging in the secondary cell set reaches its saturation to release heat, contacts on the charging assembly, on receiving said heat, will get deformed, resulting in dissociation of the insulated stretch arm on the contact that is retained by prestress, apart from the engaging receptacle, such that the secondary cell set is released, after which the prestress stored in the insulated stretch arm on the contact enabled by said prestress will break contact-to-contact coupling thus far established between the secondary cell set and the charging assembly, including alternatively disengagement of contacts on the secondary cell set only or contacts on or within the charging assembly only, and cut off the power supply forthwith. As an alternative structure, the two sets of contacts on the charging assembly may comprise entirely prestressed thermosetting of spring-functioning contacts with extension of an insulated stretch arm;   7. Those employing altogether two or more of any of the testing devices specified in item 1 through item 6 disclosed hereinbefore;   8. Those in which the structure of the charging assembly H 101  or of the secondary cell set H 102  is such that:
           (1) The secondary cell set is executed in a bar for coupling with the charging-assembly that is configured like a bee-hive; or   (2) The secondary cell set is executed in a block for coupling with the charging assembly which is also executed in a block; or   (3) The secondary cell set is executed in a block for coupling with the charging assembly which is fitted with an open chute channel to accommodate the coupling purpose; or   (4) The charging assembly and the secondary cell set are executed for coupling in a vertically upward orientation, but uncoupling in a downward orientation; coupling and uncoupling in the horizontal direction; or for coupling and uncoupling in another angular setting appropriate to specific applications;   
           9. Those in which the thermosetting structure derives its displacement due to deformation of its casing shell which is to be filled with liquid, fluid or gas, and which follows the law of expansion under heat but shrinkage when cooled, as a function of ambient temperature; or   10. Those in which said secondary cell set is composed entirely and solely of one single cell or battery, or alternatively composed of two or more cells or batteries connected in series or parallel.       

     In summation, the present invention is a charging device with stress stored by an externally applied force, the stored stress being eventually released by heat due to charging saturation, and therefore is simply structure, functionally justified, highly useful and of novel design.