CN204632746U - Chip-packaging structure - Google Patents

Abstract

The utility model provides a kind of chip-packaging structure, and it comprises: the first wafer, and the front of its wafer has the first pressure welding area and the second pressure welding area; Second wafer, the front of its wafer has the 3rd pressure welding area, the 4th pressure welding area and the 5th pressure welding area; Multiple first soldered ball; Multiple second soldered ball, its external diameter is greater than the external diameter of the first soldered ball.Wherein, the first pressure welding area on first wafer is electrically connected by the 5th pressure welding area on the first soldered ball and the second wafer, the second pressure welding area on first wafer is electrically connected by the 3rd pressure welding area on the first soldered ball and the second wafer, and the 4th pressure welding area is electrically connected with the second soldered ball.Like this, the size of the first wafer together with the second wafer package can be reduced.

Description

Chip-packaging structure

[technical field]

The utility model relates to chip package field, particularly a kind of novel chip packaging structure of battery protecting circuit.

[background technology]

General and power MOSFET (the Metal Oxide Semiconductor Field Effect Transistor of battery protection control chip in prior art, be called for short MOSFET) be made up of two kinds of different process, battery protection chip generally adopts planar technique, be conducive to integrated multiple device, the source electrode of MOSFET element wherein and drain terminal are all in the top (front) of Silicon Wafer, and power MOSFET is generally made up of vertical process, its source electrode and drain terminal are in the top (front) of Silicon Wafer and following (reverse side) respectively, channel current can run through whole wafer up and down.

In order to save cost; the chip package that some producers have started two kinds of different process to manufacture is in same encapsulation; this technology is called as SIP (System In Package); needed to encapsulate respectively battery protection control chip and power MOSFET like this; sip technique saves the cost of an encapsulation, is conducive to miniaturization simultaneously.The area that area ratio two packaging bodies of the PCB (printed circuit board (PCB): Printed Circuit Board) that packaging body takies take is less.Be generally DFN encapsulation or sot23-6 encapsulation at present.These two kinds encapsulation are all need gold thread to be connected with the formation of copper cash as package interconnects, and its thickness is comparatively large and to take PCB surface long-pending larger.Battery producer wishes to place more core material to increase battery capacity in limited battery volume, has subtract undersized demand greatly so they take PCB surface sum thickness to battery protecting circuit.The length of general Sot23-6 package dimension is 3.0 millimeters, and width is 2.8 millimeters, is highly 1.2 millimeters.The length of DFN package dimension is 3.4 millimeters, and width is 2.5 millimeters, is highly 0.7 millimeter.

Therefore, be necessary to propose a kind of new chip-packaging structure, further to reduce package dimension.

[utility model content]

The purpose of this utility model is to provide a kind of novel chip-packaging structure, and it can have less package dimension.

In order to solve the problem, the utility model provides a kind of chip-packaging structure, and it comprises: the first wafer, and the front of its wafer has the first pressure welding area and the second pressure welding area; Second wafer, the front of its wafer has the 3rd pressure welding area, the 4th pressure welding area and the 5th pressure welding area; Multiple first soldered ball; Multiple second soldered ball, its external diameter is greater than the external diameter of the first soldered ball.Wherein, the first pressure welding area on first wafer is electrically connected by the 5th pressure welding area on the first soldered ball and the second wafer, the second pressure welding area on first wafer is electrically connected by the 3rd pressure welding area on the first soldered ball and the second wafer, and the 4th pressure welding area is electrically connected with the second soldered ball.

Further, the diameter of described second soldered ball be more than or equal to the diameter of the first soldered ball and the thickness of described first wafer and.

Further, the 4th pressure welding area place is provided with gasket construction.

Further, the thickness of the first wafer and the second wafer is 100 to 200 microns.

Further, the back side of the second wafer has metal level.

Further, first wafer is that battery protection controls wafer, it includes the first control output end CO1, second control output end DO1, power end VDD, earth terminal VSS and test side VM, wherein the first pressure welding area of the first wafer comprises the pressure welding area of the first control output end CO1 and the pressure welding area of the second control output end DO1, second pressure welding area of the first wafer comprises the pressure welding area of power end VDD, the pressure welding area of earth terminal VSS and the pressure welding area of test side VM, second wafer is switch wafer, it includes the first control input end CO2, second control input end DO2, first link A and the second link B, 5th pressure welding area of the second wafer comprises the pressure welding area of the first control input end CO2 and the pressure welding area of the second control input end DO2, first control output end CO1 of the first wafer is connected by the first soldered ball with the first control input end CO2 of the second wafer, second control output end DO1 of the first wafer is connected by the first soldered ball with the second control input end DO2 of the second wafer.

Further, 3rd pressure welding area of the second wafer comprises the pressure welding area of the power end VDD of connection first wafer, the pressure welding area of the pressure welding area connecting the earth terminal VSS of the first wafer and the test side VM connecting the first wafer, 4th pressure welding area of the second wafer comprises the pressure welding area of positive external power supply end P+, the negative pressure welding area of external power supply end P-and the pressure welding area of external earth terminal, the 3rd pressure welding area be connected with the test side VM of the first wafer, the second link B in second wafer is connected with the pressure welding area of negative external power supply end P-by the path on the second wafer, the 3rd pressure welding area be connected with the earth terminal VSS of the first wafer, the first link A in second wafer is connected with the pressure welding area of external earth terminal by the path on the second wafer, the 3rd pressure welding area be connected with the power end VDD of the first wafer is connected by the pressure welding area of the path on the second wafer with positive external power supply end P+.

Further, the negative pressure welding area of external power supply end P-and the pressure welding area of external earth terminal are multiple.

Further, switch wafer comprises the first nmos pass transistor and the second nmos pass transistor, the grid of the first nmos pass transistor is the first control input end CO2, the grid of the second nmos pass transistor is the second control input end DO2, the drain electrode of the first nmos pass transistor is connected with the drain electrode of the second nmos pass transistor, the source electrode of the second nmos pass transistor is the first link A, and the source electrode of the first nmos pass transistor is the second link B.

Further; described battery protection controls wafer and comprises overcharge testing circuit, charging over-current detection circuit, overdischarge testing circuit, electric discharge over-current detection circuit and control circuit; the detection signal that described control circuit provides according to charging detecting circuit, charging over-current detection circuit, overdischarge testing circuit and electric discharge over-current detection circuit is generated charging control signal and is exported by the first control output end, generates discharge control signal and is exported by the second control output end.

Compared with prior art, first wafer and the second wafer are stacked together by the utility model in opposite directions, be connected by undersized first soldered ball between the two, second wafer is connected with the external world by larger-size second soldered ball, reduces the size of the first wafer together with the second wafer package like this.

[accompanying drawing explanation]

In order to be illustrated more clearly in the technical scheme of the utility model embodiment, below the accompanying drawing used required in describing embodiment is briefly described, apparently, accompanying drawing in the following describes is only embodiments more of the present utility model, for those of ordinary skill in the art, under the prerequisite not paying creative work, other accompanying drawing can also be obtained according to these accompanying drawings.Wherein:

Fig. 1 is the battery protecting circuit functional block diagram circuit diagram in one embodiment in the utility model;

Fig. 2 a is the chip-packaging structure side structure schematic diagram in one embodiment in the utility model;

Fig. 2 b is the chip-packaging structure plan structure schematic diagram in one embodiment in the utility model;

Fig. 3 is the structural representation of the switch wafer in the utility model.

[embodiment]

For enabling above-mentioned purpose of the present utility model, feature and advantage become apparent more, are described in further detail the utility model below in conjunction with the drawings and specific embodiments.

Alleged herein " embodiment " or " embodiment " refers to special characteristic, structure or the characteristic that can be contained at least one implementation of the utility model.Different local in this manual " in one embodiment " occurred not all refers to same embodiment, neither be independent or optionally mutually exclusive with other embodiments embodiment.Unless stated otherwise, connection herein, be connected, word that the expression that connects is electrically connected all represents and is directly or indirectly electrical connected.

Fig. 1 is the battery protecting circuit functional block diagram circuit diagram in one embodiment in the utility model.Shown in figure 1, described battery protecting circuit comprises battery protection control chip (or claiming wafer) 110 and power switch chip (or claiming wafer) 120.Described battery protecting circuit and battery BAT are electrically connected and protect the charging and discharging of described battery BAT.

Described battery protection control chip 110 and power switch chip 120 can adopt and be encapsulated in an encapsulation, and hereafter by detailed description, how they are encapsulated in an encapsulation.

Battery protection control chip 110 comprises the first control output end CO1, the second control output end DO1, power end VDD, earth terminal VSS and test side VM.Power switch chip 120 includes the first control input end CO2, the second control input end DO2, the first link A and the second link B.

Wherein, the first control output end CO1 is connected with the first control input end CO2, and the second control output end DO1 is connected with the second control input end DO2.Positive pole and the positive external power supply end P+ of power end VDD and battery BAT are connected, and negative pole and the first link A of earth terminal VSS and battery BAT are connected.Test side VM is connected with the second link B and negative external power supply end P-.Battery charger 130 can be connected between positive external power supply end P+ and negative external power supply end P-, also can connect load resistance R0.When load resistance Ro is connected between positive external power supply end P+ and negative external power supply end P-, described battery BAT is in discharge condition, when battery charger 130 is just being connected between positive external power supply end P+ and negative external power supply end P-, described battery BAT is being in charged state.

Described battery protection control chip 110 comprises overcharge testing circuit 112, charging over-current detection circuit 114, overdischarge testing circuit 116, electric discharge over-current detection circuit 118 and control circuit 119.Described overcharge testing circuit 112, charging over-current detection circuit 114, overdischarge testing circuit 116 and electric discharge over-current detection circuit 118 can be collectively referred to as threshold detection circuit.The detection signal that described control circuit 119 provides according to charging detecting circuit 112, charging over-current detection circuit 114, overdischarge testing circuit 116 and electric discharge over-current detection circuit 118 is generated charging control signal and is exported by the first control output end CO1, generates discharge control signal and is exported by the second control output end DO1.

Described power switch chip 120 comprises a NMOS (N-channel Metal-Oxide-Semiconductor, N-type metal-oxide semiconductor (MOS)) the transistor MC and the second nmos pass transistor MD connected successively.The drain electrode of described first nmos pass transistor is connected to form mutual connection end K with the drain electrode of described second nmos pass transistor, thus formation is connected in series; The source electrode of described first nmos pass transistor MC is connected with lining body, and as the second link B of described power switch chip 120, the source electrode of described second nmos pass transistor MD is connected, as the first link A of described power switch chip 120 with lining body; The grid of described first nmos pass transistor is as the first control input end CO2 of described power switch chip 120, and the grid of described second nmos pass transistor is as the second control input end DO2 of described power switch chip 120.

Please refer to shown in Fig. 3, it is the structural representation of power switch chip 120 in Fig. 1.The left side is the second nmos pass transistor MD, and the right is the first nmos pass transistor MC, and wherein one end of the first nmos pass transistor and the second nmos pass transistor shares, thus formation is connected in series.As shown in Figure 3, this nmos pass transistor is vertical stratification.During conducting, its electric current flows perpendicular to the direction of wafer surface, and electric current can flow to mutual connection end K from the first link A end and hold, and then flows to the second link B and holds.In P-and N--number expression doping content is lower, N+ and P+ (+number expression doping content is higher) is for the formation of the ohmic contact less with Metal Contact resistance.P+ forms the lining body contact of nmos pass transistor, because lining body P+ links together (namely connecting current potential identical) all the time with contiguous N+ electrode, in order to reduce area, collision type (Butting) is generally adopted to design, together with namely P+ with N+ abuts against.Oblique line fill area is the grid of nmos pass transistor.When grid voltage exceedes threshold voltage, make and P-region transoid between N+ electrode that P+ is contiguous and another electrode N-region, namely attract a lot of electronics to be positioned near gate electrode side, be communicated with by the N+ electrode that P+ is contiguous like this with N-electrode, such nmos pass transistor is with regard to conducting.

As shown in Figure 1, overcharge testing circuit 112 detects battery core voltage (voltage between VDD and VSS) and whether is greater than overvoltage charging detection threshold (such as 4.3V), if, be then low level by control first control output end CO1, to be turned off by the first nmos pass transistor, thus cut off charging path.

Whether overdischarge testing circuit 116 is less than overvoltage discharge examination threshold value (such as 2.5V) for detecting battery core voltage (voltage between VDD and VSS), if, be then low level by control second control output end DO1, to be turned off by the second nmos pass transistor, thus cut off discharge path.

Electric discharge over-current detection circuit 118 detects by test side (VM) the whether overcurrent of discharging, such as, if when VM voltage is higher than+150mV, be then low level by control second control output end DO1, to be turned off by the second nmos pass transistor, thus cut off discharge path.

Charging over-current detection circuit 114 detects by test side (VM) the whether overcurrent of charging, such as, if when VM voltage is lower than-150mV, be low level by controlling the first control output end CO1, to be turned off by the first nmos pass transistor, thus cut off charging path.

In addition; also short-circuit detecting circuit is included in described battery protection control chip 110; it equally detects whether short circuit by test side (VM); such as; if when VM voltage is higher than 1V; be then low level by control second control output end DO1, to be turned off by the second nmos pass transistor, thus cut off discharge path.

In traditional battery protection control chip, need to add in chip exterior and be connected to resistance R1 on vdd terminal and electric capacity C1, need the resistance R2 be connected on VM end simultaneously.The function of resistance R1 and electric capacity C1 has 2 points: one is prevent when there is instantaneous pressure in system; battery protecting circuit is avoided to break; maximum withstand voltage between the VDD/VSS of general battery protection design on control circuit is 12V; an example is when being short-circuited between P+/P-; protective circuit can cut off discharge path (by turning off the second NMOS tube); now stray inductance can produce flyback voltage, up to about 15V, puts between VDD/VSS.Two is carry out filtering to vdd voltage, prevents the trigger protection circuit erroneous action due to vdd voltage noise.The effect of resistance R2 prevents charger from connecing inverse time, carries out current limliting, avoid battery protection control circuit to damage to the electric current flowing into battery protection control circuit.Integrated resistor R1, C1 and R2 can be realized, the battery protection control chip in the utility model in Fig. 1 is just built-in R1, C1 and R2, without the need to extra resistance R1, R2 and electric capacity C1 by suitable designing technique.

Fig. 2 a is the side structure schematic diagram of the chip-packaging structure in the utility model, and Fig. 2 b is the plan structure schematic diagram of the chip-packaging structure in the utility model.

As shown in figures 2 a and 2b, described chip-packaging structure includes the first wafer 210, second wafer 220, multiple first soldered ball 230 and multiple second soldered ball 240.The external diameter of the second soldered ball 240 is greater than the external diameter of the first soldered ball 230.In one embodiment, the diameter of described second soldered ball be more than or equal to the diameter of the first soldered ball and the thickness of described first wafer 210 and.The thickness of whole chip-packaging structure can be made so very little.

Wherein the front of the first wafer 210 has the first pressure welding area and the second pressure welding area, and the front of the second wafer 220 has the 3rd pressure welding area, the 4th pressure welding area (region of corresponding second soldered ball 240) and the 5th pressure welding area.

The installation of the vis-a-vis of the first wafer 210 and the second wafer 220, that is, the first wafer 210 and the second wafer 220 are stacked, and can reduce length and the width of chip-packaging structure like this.Wherein, the first pressure welding area on first wafer 210 is electrically connected by the 5th pressure welding area on the first soldered ball 230 and the second wafer 220, the second pressure welding area on first wafer 210 is electrically connected by the 3rd pressure welding area on the first soldered ball and the second wafer, the 4th pressure welding area is electrically connected with the second soldered ball 240.

In one embodiment, the 4th pressure welding area place is provided with gasket construction 250, better to make the second soldered ball 240 be connected with the 4th pressure welding area, forms lower connection impedance.

First wafer 210 can be that the battery protection in Fig. 1 controls wafer 110.First pressure welding area of the first wafer 210 comprises the pressure welding area (the CO dashed region in Fig. 2 b) of the first control output end CO1 and the pressure welding area (the DO dashed region in Fig. 2 b) of the second control output end DO1, and the second pressure welding area of the first wafer 210 comprises the pressure welding area of power end VDD (the VDD dashed region in Fig. 2 b), the pressure welding area (the VSS dashed region in Fig. 2 b) of earth terminal VSS and the pressure welding area (VSS dashed region) of test side VM.

Second wafer 220 can be the switch wafer 120 in Fig. 1.5th pressure welding area of the second wafer 220 comprises the pressure welding area of the first control input end CO2 and the pressure welding area of the second control input end DO2.First control output end CO1 of the first wafer 210 is connected by the first soldered ball with the first control input end CO2 of the second wafer 220, and the second control output end DO1 of the first wafer 210 is connected by the first soldered ball with the second control input end DO2 of the second wafer 220.This connection distance is very short, connects and the resistance of formation is also very little.3rd pressure welding area of the second wafer 220 comprise by the first soldered ball 230 connect the power end VDD of the first wafer 210 pressure welding area, connected the pressure welding area of the earth terminal VSS of the first wafer 210 by the first soldered ball 230 and connected the pressure welding area of test side VM of the first wafer 210 by the first soldered ball 230.

It is understood that the position of the 5th pressure welding area on the second wafer 220 is relative with the first pressure welding area of the first wafer 210, the position of the 3rd pressure welding area on the second wafer 220 is relative with the second pressure welding area of the first wafer 210.

As shown in Figure 2 b, described second soldered ball 240 comprises the second soldered ball 241 be connected with positive external power supply end P+, the second soldered ball 242 be connected with negative external power supply end P-, the 3rd soldered ball 243 be connected with external earth terminal.4th pressure welding area of the second wafer 210 comprises the pressure welding area (region of the second soldered ball 241 correspondence in Fig. 2 b) of positive external power supply end P+, the negative pressure welding area (region of the second soldered ball 242 correspondence in Fig. 2 b) of external power supply end P-and the pressure welding area (region of the second soldered ball 243 correspondence in Fig. 2 b) of external earth terminal.

In figure 2b, the second soldered ball 241 be connected with positive external power supply end P+ only has 1, the second soldered ball 242 be connected with negative external power supply end P-has four (the right one vertical setting of types in Fig. 2 b), to reduce conducting resistance, the 3rd soldered ball 243 be connected with external earth terminal has four (left side one vertical setting of types in Fig. 2 b), to reduce conducting resistance.

As shown in figures 2 a and 2b, the second link B in the 3rd pressure welding area be connected with the test side VM of the first wafer and the second wafer is connected by the pressure welding area of the path on the second wafer 220 with negative external power supply end P-.The first link A in the 3rd pressure welding area be connected with the earth terminal VSS of the first wafer 210 and the second wafer 220 is connected with the pressure welding area of external earth terminal by the path on the second wafer 220.The 3rd pressure welding area be connected with the power end VDD of the first wafer 210 is connected by the pressure welding area of the path on the second wafer 220 with positive external power supply end P+.

First wafer 210 and the second wafer 220 can be realized being electrically connected with battery Bat and outside charger or load resistance by the second soldered ball 240.

In one embodiment, extra preliminary treatment can be done to the second wafer 220 after machining, so that the impedance that the drain electrode reducing the first nmos pass transistor is connected with the drain electrode of the second nmos pass transistor.One method is after the second wafer completes traditional manufacturing process, in bottom additional deposition super thick metal level 221 (as shown in Figure 2 a) of the second wafer.In certain embodiments, this metal can be aluminium, or copper or comprise the alloy material of aluminium or copper.This depositing metal step should before the second wafer cuts into wafer by wafer.In another embodiment, after the wafer of manufacture second wafer completes Conventional process steps, by spin coating proceeding at wafer lower surface spin coating conductive silver paste, such as silver content is equal to or greater than the epoxy material of 80%.In a preferred embodiment, the thickness of the auxiliary metal layer 221 in the utility model is more than or equal to 5um.The thickness increasing metal level 221 contributes to realizing less conducting resistance.

In order to realize the preferred version of less thickness, when the wafer of manufacture second wafer, also should increase wafer reduction steps, before deposited metal or spin coating metal level 221, reply wafer carries out thinning, such as, can be thinned to the thickness of 100 ~ 200 microns.When the wafer of manufacture first wafer, also should increase wafer reduction steps, carry out of the present utility model plant ball step before, the first wafer should be thinned to the thickness of 100 ~ 200 microns.

Novel chip packaging structure of the present utility model, will realize the size less than prior art, such as length 1.8 millimeters, width 0.8 millimeter, height 0.5 millimeter.

In the utility model, " connection ", be connected, word that " companys ", the expression such as " connecing " are electrical connected, if no special instructions, then represent direct or indirect electric connection.

It is pointed out that the scope be familiar with person skilled in art and any change that embodiment of the present utility model is done all do not departed to claims of the present utility model.Correspondingly, the scope of claim of the present utility model is also not limited only to previous embodiment.

Claims (10)

1. a chip-packaging structure, is characterized in that, it comprises:

First wafer, the front of its wafer has the first pressure welding area and the second pressure welding area;

Second wafer, the front of its wafer has the 3rd pressure welding area, the 4th pressure welding area and the 5th pressure welding area;

Multiple first soldered ball;

Multiple second soldered ball, its external diameter is greater than the external diameter of the first soldered ball;

Wherein, the first pressure welding area on the first wafer is electrically connected by the 5th pressure welding area on the first soldered ball and the second wafer, and the second pressure welding area on the first wafer is electrically connected by the 3rd pressure welding area on the first soldered ball and the second wafer,

4th pressure welding area is electrically connected with the second soldered ball.

2. chip-packaging structure according to claim 1, is characterized in that, the diameter of described second soldered ball be more than or equal to the diameter of the first soldered ball and the thickness of described first wafer and.

3. chip-packaging structure according to claim 1, is characterized in that, the 4th pressure welding area place is provided with gasket construction.

4. chip-packaging structure according to claim 1, is characterized in that,

The thickness of the first wafer and the second wafer is 100 to 200 microns.

5. chip-packaging structure according to claim 1, is characterized in that,

The back side of the second wafer has metal level.

6., according to the arbitrary described chip-packaging structure of claim 1-5, it is characterized in that,

First wafer is that battery protection controls wafer, and it includes the first control output end CO1, the second control output end DO1, power end VDD, earth terminal VSS and test side VM, wherein

First pressure welding area of the first wafer comprises the pressure welding area of the first control output end CO1 and the pressure welding area of the second control output end DO1, and the second pressure welding area of the first wafer comprises the pressure welding area of power end VDD, the pressure welding area of earth terminal VSS and the pressure welding area of test side VM,

Second wafer is switch wafer, it includes the first control input end CO2, the second control input end DO2, the first link A and the second link B, 5th pressure welding area of the second wafer comprises the pressure welding area of the first control input end CO2 and the pressure welding area of the second control input end DO2, first control output end CO1 of the first wafer is connected by the first soldered ball with the first control input end CO2 of the second wafer, and the second control output end DO1 of the first wafer is connected by the first soldered ball with the second control input end DO2 of the second wafer.

7. chip-packaging structure according to claim 6, is characterized in that,

3rd pressure welding area of the second wafer comprises the pressure welding area of the test side VM of the pressure welding area of the power end VDD of connection first wafer, the pressure welding area connecting the earth terminal VSS of the first wafer and connection the first wafer,

4th pressure welding area of the second wafer comprises the pressure welding area of positive external power supply end P+, the negative pressure welding area of external power supply end P-and the pressure welding area of external earth terminal,

The second link B in the 3rd pressure welding area be connected with the test side VM of the first wafer, the second wafer is connected by the pressure welding area of the path on the second wafer with negative external power supply end P-,

The first link A in the 3rd pressure welding area be connected with the earth terminal VSS of the first wafer, the second wafer is connected by the pressure welding area of the path on the second wafer with external earth terminal,

The 3rd pressure welding area be connected with the power end VDD of the first wafer is connected by the pressure welding area of the path on the second wafer with positive external power supply end P+.

8. chip-packaging structure according to claim 7, is characterized in that, the negative pressure welding area of external power supply end P-and the pressure welding area of external earth terminal are multiple.

9. chip-packaging structure according to claim 6, is characterized in that,

Switch wafer comprises the first nmos pass transistor and the second nmos pass transistor,

The grid of the first nmos pass transistor is the first control input end CO2, and the grid of the second nmos pass transistor is the second control input end DO2,

The drain electrode of the first nmos pass transistor is connected with the drain electrode of the second nmos pass transistor,

The source electrode of the second nmos pass transistor is the first link A, and the source electrode of the first nmos pass transistor is the second link B.

10. chip-packaging structure according to claim 6; it is characterized in that; described battery protection controls wafer and comprises overcharge testing circuit, charging over-current detection circuit, overdischarge testing circuit, electric discharge over-current detection circuit and control circuit; the detection signal that described control circuit provides according to charging detecting circuit, charging over-current detection circuit, overdischarge testing circuit and electric discharge over-current detection circuit is generated charging control signal and is exported by the first control output end, generates discharge control signal and is exported by the second control output end.