CN203722209U - Over-current protection device and intelligent power module, and variable-frequency household appliance - Google Patents

Abstract

The utility model provides an over-current protection device. The device comprises a comparison circuit which is connected to a current sampling unit in an intelligent power module and used for comparing a real-time voltage analog signal from the current sampling unit with a standard voltage analog signal numerically and generating a corresponding analog control signal based on the comparison result; and an integration circuit which is connected to the comparison circuit and a controller corresponding to the intelligent power module and used for integrating an analog time sequence signal from the controller with the analog control signal and outputting the integrated analog time sequence signal to the intelligent power module. The utility model also provides the intelligent power module and a variable-frequency household appliance. With the employment of the utility model, the over-current protection can be realized in a more rapid manner when the intelligent power module has abnormalities, such as interference, cylinder blockage, voltage dip and the like, thereby preventing the potential safety hazards generated by control delay.

Description

Overcurrent protective device and Intelligent Power Module, frequency-conversion domestic electric appliances

Technical field

The utility model relates to current protection technology field, in particular to a kind of overcurrent protective device, a kind of Intelligent Power Module and a kind of frequency-conversion domestic electric appliances.

Background technology

Intelligent Power Module, i.e. IPM(Intelligent Power Module), be a kind of by the power drive series products of power electronics and integrated circuit technique combination.Intelligent Power Module integrates device for power switching and high-voltage driving circuit, and in keep overvoltage, overcurrent and the failure detector circuit such as overheated.Intelligent Power Module receives the control signal of MCU on the one hand, drives subsequent conditioning circuit work, sends the state detection signal of system back to MCU on the other hand.Compare with traditional discrete scheme, Intelligent Power Module wins increasing market with advantages such as its high integration, high reliability, being particularly suitable for frequency converter and the various inverter of drive motors, is a kind of desirable power electronic device that is applied to frequency control, metallurgical machinery, electric traction, servo-drive, frequency-conversion domestic electric appliances.

As shown in Figure 1, be the structural representation of a kind of Intelligent Power Module of proposing in correlation technique.Particularly, this Intelligent Power Module 100 comprises: drive chip 101 and IGBT(Insulated Gate Bipolar Transistor, insulated gate bipolar transistor) pipe 121～126.

Driving chip 101 inside to have boostrap circuit, boostrap circuit structure is as follows: drive the VCC end of chip 101 to be connected with the anode of bootstrap diode 101A, bootstrap diode 101B, bootstrap diode 101C; The negative electrode of described bootstrap diode 101A is connected with VB1; The negative electrode of described bootstrap diode 101B is connected with VB2; The negative electrode of described bootstrap diode 101C is connected with VB3.

The concrete annexation of each pin of driving chip 101 and IGBT pipe 121～126 etc. is as follows:

Drive the VCC end of chip 101 as the low-pressure area power supply anode VDD of described Intelligent Power Module 100, VDD is generally 15V; Drive the GND end of chip 101 as the low-pressure area power supply negative terminal COM of described Intelligent Power Module 100.

Drive the HIN1 of chip 101 to hold the U as described Intelligent Power Module 100 to go up mutually brachium pontis input UHIN; Drive the HIN2 of chip 101 to hold the V as described Intelligent Power Module 100 to go up mutually brachium pontis input VHIN; Drive the HIN3 of chip 101 to hold the W as described Intelligent Power Module 100 to go up mutually brachium pontis input WHIN; Drive the LIN1 of chip 101 to hold the U as described Intelligent Power Module 100 to descend mutually brachium pontis input ULIN; Drive the LIN2 of chip 101 to hold the V as described Intelligent Power Module 100 to descend mutually brachium pontis input VLIN; Drive the LIN3 of chip 101 to hold the W as described Intelligent Power Module 100 to descend mutually brachium pontis input WLIN(at this, the U of described Intelligent Power Module 100, V, the input of W three-phase Liu road receive the input signal of 0～5V).

Drive the VB1 end of chip 101 to connect one end of electric capacity 131, and as the U phase higher-pressure region power supply anode UVB of described Intelligent Power Module 100; Drive the HO1 end of chip 101 to be connected with the grid that U goes up brachium pontis IGBT pipe 121 mutually; Drive the VS1 end of chip 101 and the emitter-base bandgap grading of described IGBT pipe 121, anode, the U of FRD pipe (fast recovery diode) 111 descend brachium pontis IGBT to manage that 124 collector electrode, FRD manage 114, the negative electrode of the other end of electric capacity 131 is connected mutually, and as the U phase higher-pressure region power supply negative terminal UVS of described Intelligent Power Module 100.

Drive the VB2 end of chip 101 to connect one end of electric capacity 132, and as the V phase higher-pressure region power supply anode VVB of described Intelligent Power Module 100; Drive the HO3 end of chip 101 to be connected with the grid that V goes up brachium pontis IGBT pipe 123 mutually.The collector electrode of brachium pontis IGBT pipe 125, FRD manage 115 negative electrode, the other end of electric capacity 132 is connected, anode, the V of FRD pipe 112 descend mutually to drive the VS2 end of chip 101 and the emitter-base bandgap grading of described IGBT pipe 122, and as the W phase higher-pressure region power supply negative terminal VVS of described Intelligent Power Module 100.

Drive the VB3 end of chip 101 to connect one end of electric capacity 133, and as the W phase higher-pressure region power supply anode WVB of described Intelligent Power Module 100; Drive the HO3 end of chip 101 to be connected with the grid that W goes up brachium pontis IGBT pipe 123 mutually; The collector electrode of brachium pontis IGBT pipe 126, FRD manage 116 negative electrode, the other end of electric capacity 133 is connected, anode, the W of FRD pipe 113 descend mutually to drive the VS3 end of chip 101 and the emitter-base bandgap grading of described IGBT pipe 123, and as the W phase higher-pressure region power supply negative terminal WVS of described Intelligent Power Module 100.

Drive the LO1 end of chip 101 to be connected with the grid of described IGBT pipe 124; Drive the LO2 end of chip 101 to be connected with the grid of described IGBT pipe 125; Drive the LO3 end of chip 101 to be connected with the grid of described IGBT pipe 126.

The emitter-base bandgap grading of described IGBT pipe 124 is connected with the anode of described FRD pipe 114, and as the U phase low reference voltage end UN of described Intelligent Power Module 100; The emitter-base bandgap grading of described IGBT pipe 125 is connected with the anode of described FRD pipe 115, and as the V phase low reference voltage end VN of described Intelligent Power Module 100; The emitter-base bandgap grading of described IGBT pipe 126 is connected with the anode of described FRD pipe 116, and as the W phase low reference voltage end WN of described Intelligent Power Module 100.

The negative electrode of the collector electrode of the negative electrode of the collector electrode of the negative electrode of the collector electrode of described IGBT pipe 121, described FRD pipe 111, described IGBT pipe 122, described FRD pipe 112, described IGBT pipe 123, described FRD pipe 113 is connected, and as the high voltage input P of described Intelligent Power Module 100, P generally meets 300V.

Based on above-mentioned annexation, drive the effect of chip 101 to be:

The logical signal of 0～5V of input HIN1, HIN2, HIN3 and LIN1, LIN2, LIN3 is passed to respectively to output HO1, HO2, HO3 and LO1, LO2, LO3, wherein HO1, HO2, HO3 are the logical signals of VS～VS+15V, and LO1, LO2, LO3 are the logical signals of 0～15V.Wherein, the input signal of same phase can not be high level simultaneously, and HIN1 and LIN1, HIN2 and LIN2, HIN3 and LIN3 can not be high level simultaneously.

Recommendation circuit during Intelligent Power Module 100 real work is as shown in Figure 2:

Between UVB and UVS, external capacitor 135; Between VVB and VVS, external capacitor 136; Between WVB and WVS, external capacitor 137.Herein, electric capacity 133, electric capacity 132, electric capacity 131 mainly strobe, and electric capacity 135, electric capacity 136, electric capacity 137 mainly play storing electricity effect.

UN, VN, the connected also one end of connecting resistance 138 of WN, and the Pin7 of MCU200; Another termination COM of described resistance 138; MCU200 the UHIN end of Pin1 and described Intelligent Power Module 100 be connected; MCU200 the VHIN end of Pin2 and described Intelligent Power Module 100 be connected; MCU200 the WHIN end of Pin3 and described Intelligent Power Module 100 be connected; MCU200 the ULIN end of Pin4 and described Intelligent Power Module 100 be connected; MCU200 the VLIN end of Pin5 and described Intelligent Power Module 100 be connected; MCU200 the WLIN end of Pin6 and described Intelligent Power Module 100 be connected.

In conjunction with Fig. 1 and Fig. 2, the U of take below illustrates the operating state of Intelligent Power Module 100 mutually as example:

1, the first state

When the Pin4 of MCU200 sends high level signal, the Pin1 of MCU200 must send low level signal, it is that high level, HIN1 are low level that signal makes LIN1, LO1 exports high level and HO1 output low level, described IGBT pipe 121 cut-offs thereby described IGBT manages 124 conductings, VS1 voltage is about 0V.Meanwhile, bootstrap diode 101A forward bias, makes 135 chargings of electric capacity 133 and electric capacity, when time long enough or make electric capacity 133 and electric capacity 135 chargings before dump energy when abundant, VB1 obtains the voltage that approaches 15V to VS1.

2, the second state

When the Pin1 of MCU200 sends high level signal, the Pin4 of MCU200 must send low level signal, it is that low level, HIN1 are high level that signal makes LIN1, LO1 output low level and HO1 output high level, thereby IGBT pipe 124 cut-offs and IGBT manages 121 conductings, thus VS1 voltage is about 300V, and VB1 voltage is lifted to 315V left and right, by the electric weight of electric capacity 133 and electric capacity 135, maintain the work of U phase higher-pressure region.Wherein, if the duration that HIN1 is high level, enough the electric weight of short or electric capacity 133 and electric capacity 135 storages was abundant, VB1 is more than to VS1, the voltage in the course of work of U phase higher-pressure region can remain on 14V.

In the MCU algorithm of practical application, it is conducting that U phase, V phase, W always have the upper brachium pontis IGBT of a minimum phase mutually, and always having the lower brachium pontis IGBT of a minimum phase is conducting, and the IGBT of conducting pipe is not in same phase.Therefore, when real work, resistance 138 continues to have electric current to flow through, and produces voltage at the Pin7 of MCU200.Yet; owing to disturbing, blocking cylinder, voltage collapse etc. extremely; the electric current that flows through resistance 138 can become large; if electric current is greater than a certain particular value; make the pressure drop at resistance 138 two ends be greater than a certain particular value, the Pin7 of MCU200 becomes after large signal electric voltage exception being detected, will make Pin1, Pin2, Pin3, Pin4, the whole output low levels of Pin5, Pin6; Intelligent Power Module 100 is quit work, Here it is overcurrent protection function.

But, MCU200 is not real-time to the sampling of resistance 138 both end voltage, have certain time interval, and in the sampling of MCU200 and overcurrent protection control procedure, need to experience repeatedly modulus or digital-to-analogue conversion, make abnormal voltage to be detected to making Pin1 from MCU200, Pin2, Pin3, Pin4, Pin5, Pin6 output sets low institute's elapsed time generally can be in 10 μ s left and right, if it is enough large to flow through the electric current of resistance 138, within the time of 10 μ s, IGBT pipe and resistance 138 on current path are all likely impaired, overheated burning even, when serious, also can set off an explosion.

Therefore, how when carrying out overcurrent protection, avoid postponing the potential safety hazard brought, become technical problem urgently to be resolved hurrily at present.

Utility model content

The utility model is intended at least solve one of technical problem existing in prior art or correlation technique.

For this reason, an object of the present utility model is to have proposed a kind of overcurrent protective device.

Another object of the present utility model is to have proposed a kind of Intelligent Power Module.

Another object of the present utility model is to have proposed a kind of frequency-conversion domestic electric appliances.

For achieving the above object, according to the embodiment of first aspect of the present utility model, a kind of overcurrent protective device has been proposed, comprise: comparison circuit, be connected to the current sample element in Intelligent Power Module, for the real-time voltage analog signal from described current sample element and normal voltage analog signal are carried out to numeric ratio, and generate corresponding analog control signal according to comparative result; Integrated circuit, be connected to described comparison circuit and corresponding to the controller of described Intelligent Power Module, for the simulated timing diagrams signal from described controller and described analog control signal are integrated, and export the simulated timing diagrams signal after integrating to described Intelligent Power Module.

In this technical scheme; in control procedure during by the collection at current signal, comparison and overcurrent protection; all use analog signal to process; make without the analog signal in execution MCU processing procedure and the conversion operations between digital signal; thereby can shorten and from signals collecting to reality, carry out the delay in overcurrent protection control procedure; while avoiding electric current larger, cause Intelligent Power Module to be just damaged within time of delay; effectively promote the safety in utilization of Intelligent Power Module, eliminated potential safety hazard.

Simultaneously; owing to adopting the sampling of analog signal, the processing procedure such as relatively; make it possible at any time the current conditions on current sample element be fed back, accomplish real-time overcurrent protection, avoid as much as possible fortuitous event to cause Intelligent Power Module generation security incident.

It should be noted that, current sample element is the indeclinable element of resistance generally, such as resistance, for the current conditions on current sample element, be actually and feed back by change in voltage, thereby be actually by the comparison to real-time voltage analog signal and normal voltage analog signal, to determine whether to occur overcurrent condition.

In addition, according to the overcurrent protective device of the utility model above-described embodiment, can also there is following additional technical characterictic:

According to an embodiment of the present utility model, preferably, in the situation that described real-time voltage analog signal is more than or equal to described normal voltage analog signal, described analog control signal is the first analog control signal, and the simulated timing diagrams signal after described integration is low level signal; In the situation that described real-time voltage analog signal is less than described normal voltage analog signal, described analog control signal is the second analog control signal, and the simulated timing diagrams signal after described integration is identical with the simulated timing diagrams signal from described controller.

In this technical scheme, when there is overcurrent condition, to cause real-time voltage analog signal to be more than or equal to normal voltage analog signal, the What gives of the simulated timing diagrams signal of controller output no matter now, all directly to all of the port input low level signal of Intelligent Power Module, all IGBT pipes are all quit work, thereby can realize overcurrent protection fast; And when not there is not overcurrent condition, real-time voltage analog signal is less than normal voltage analog signal, by making simulated timing diagrams signal constant before and after integrating, thereby guarantee can not impact the course of normal operation of Intelligent Power Module.

Preferably, described comparison circuit comprises: comparator, the positive input terminal of described comparator accesses described normal voltage analog signal, negative input end accesses described real-time voltage analog signal, and output is connected to described integrated circuit.

In this technical scheme, processing procedure for mating die analog signal, can adopt as comparator and realize real-time voltage analog signal and normal voltage analog signal are compared, thereby can carry out fast whether the judgement of overcurrent condition occurring, and make accordingly corresponding processing.

Preferably, described integrated circuit comprises a plurality of identical integron circuit, one by one corresponding to a plurality of output ports of described controller and a plurality of input ports of described Intelligent Power Module, wherein, described in each, integron circuit comprises: first input end, be connected to the default output port of described controller, for receiving corresponding simulated timing diagrams signal; The second input, is connected to described comparison circuit, for receiving described analog control signal; Output, be connected to the default input port of described Intelligent Power Module, in the situation that described analog control signal is high level signal, export described simulated timing diagrams signal, and in the situation that described analog control signal is low level signal, output low level signal.

In this technical scheme; corresponding to each the IGBT pipe in Intelligent Power Module; controller all needs to input corresponding simulated timing diagrams signal by corresponding pin; can to the simulated timing diagrams signal of respective pin, process by each integron circuit, thereby realize, the overcurrent protection of all IGBT pipes be controlled.

Preferably, described in each, integron circuit comprises: NAND gate, and two inputs of described NAND gate are connected to respectively described first input end and described the second input; Or door, input described or door is connected to the output of described NAND gate, and output described or door is connected to the output of the integron circuit that comprises described or door.

In this technical scheme; as a kind of comparatively preferred embodiment; can adopt concrete gate circuit to realize processes the integration of simulated timing diagrams signal; thereby by logical process processes such as the quick comparison of analog signal, integration, realize the overcurrent protection fast and accurately to Intelligent Power Module.

According to another embodiment of the present utility model, preferably, also comprise: signal generating circuit, be connected to described comparison circuit and described Intelligent Power Module, for responding to the real time temperature situation of described Intelligent Power Module, and generate described normal voltage analog signal according to described real time temperature situation, wherein, the numerical values recited of described real-time voltage analog signal and described normal voltage analog signal consistently changes with the variation of described real time temperature situation.

In this technical scheme, because variations in temperature may cause the resistance of current sample element, change, and while making to carry out according to normal overcurrent protection logic, may cause that erroneous judgement occurs disconnected.Therefore, by the induction of the real time temperature situation to Intelligent Power Module, can make the logic of overcurrent protection to change with the variations in temperature of Intelligent Power Module, avoid judging by accident disconnected generation.

Preferably, the numerical values recited of described real-time voltage analog signal and described normal voltage analog signal is all proportionate with described real time temperature situation.

In this technical scheme, when voltage swing and real time temperature situation are proportionate, when the temperature of Intelligent Power Module raises, will cause the numerical value of real-time voltage analog signal to increase; And by the numerical value of normal voltage analog signal is increased, thereby can avoid the disconnected normal operating conditions that causes affecting Intelligent Power Module of erroneous judgement.

Preferably, described signal generating circuit comprises: the first DC power supply; The first temperature sensitive member, one end of described the first temperature sensitive member is connected to the positive pole of described the first DC power supply and described comparison circuit, the other end and described Intelligent Power Module altogether.

In this technical scheme, as a kind of comparatively concrete execution mode, the temperature sensitive member of (being herein altogether) can be connected with Intelligent Power Module by adopting, the induction of realization to the real time temperature situation of Intelligent Power Module, especially the Intelligent Power Module in correlation technique in the course of the work, overall work uniformity of temperature profile, thereby can come the working temperature of Intelligent Power Module to realize induction exactly by above-mentioned temperature sensitive member.

Particularly, because the current value of the first DC power supply is constant, while causing the change in resistance of the first temperature sensitive member when variations in temperature, variations in temperature may be embodied on the voltage value of the first temperature sensitive member input comparison circuit.

According to another embodiment of the present utility model, preferably, also comprise: temperature regime output circuit, is connected to described Intelligent Power Module and described controller, for exporting the circuit characteristic parameter information of the real time temperature situation corresponding to described Intelligent Power Module to described controller.

In this technical scheme, because no longer carrying out current control to Intelligent Power Module, controller controlled, also cannot carry out the temperature detection to Intelligent Power Module, thereby by exporting the real time temperature situation of Intelligent Power Module to controller, make controller can realize accordingly more control function.Particularly, as a kind of comparatively preferred embodiment, such as controller can be according to the real time temperature situation of Intelligent Power Module, control the operating frequency of Intelligent Power Module; Further, when real time temperature is higher, can reduce the operating frequency of Intelligent Power Module, when real time temperature is lower, the operating frequency of the Intelligent Power Module that can raise.

Preferably, described temperature regime output circuit comprises: the second DC power supply; The second temperature sensitive member, one end of described the second temperature sensitive member is connected to the positive pole of described the second DC power supply and described controller, the other end and described Intelligent Power Module altogether.

In this technical scheme, as a kind of comparatively specific embodiment, can to Intelligent Power Module, carry out temperature sense by temperature sensitive member, the working temperature due to Intelligent Power Module is evenly distributed, thereby can realize the accurate detection to Intelligent Power Module by temperature sensitive member.

Particularly, because the current value of the second DC power supply is constant, while causing the change in resistance of the second temperature sensitive member when variations in temperature, variations in temperature may be embodied on the voltage value of the second temperature sensitive member input control device.

According to the embodiment of the utility model second aspect, a kind of Intelligent Power Module has been proposed, comprise the overcurrent protective device as described in any one in technique scheme.

According to the embodiment of the utility model third aspect, a kind of frequency-conversion domestic electric appliances has been proposed, comprise above-mentioned Intelligent Power Module.

By above technical scheme, can disturb in Intelligent Power Module, block cylinder, voltage collapse etc. when abnormal, more promptly realize overcurrent protection, the potential safety hazard of avoiding control lag to cause.

Additional aspect of the present utility model and advantage in the following description part provide, and part will become obviously from the following description, or recognize by practice of the present utility model.

Accompanying drawing explanation

Above-mentioned and/or additional aspect of the present utility model and advantage accompanying drawing below combination obviously and is easily understood becoming the description of embodiment, wherein:

Fig. 1 shows the structural representation of the Intelligent Power Module in correlation technique;

Fig. 2 show in correlation technique Intelligent Power Module is carried out to sequencing control time structural representation;

Fig. 3 shows according to the structural representation of the overcurrent protective device of an embodiment of the present utility model;

Fig. 4 shows according to the structural representation of the overcurrent protective device of another embodiment of the present utility model;

Fig. 5 shows according to the structural representation of the Intelligent Power Module of an embodiment of the present utility model;

Fig. 6 shows the concrete structure schematic diagram according to the overcurrent protective device of an embodiment of the present utility model;

Fig. 7 shows the concrete structure schematic diagram according to the overcurrent protective device of another embodiment of the present utility model;

Fig. 8 shows the concrete structure schematic diagram according to the overcurrent protective device of another embodiment of the present utility model.

Embodiment

In order more clearly to understand above-mentioned purpose of the present utility model, feature and advantage, below in conjunction with the drawings and specific embodiments, the utility model is further described in detail.It should be noted that, in the situation that not conflicting, the application's embodiment and the feature in embodiment can combine mutually.

A lot of details have been set forth in the following description so that fully understand the utility model; but; the utility model can also adopt other to be different from other modes described here and implement, and therefore, protection range of the present utility model is not limited to the restriction of following public specific embodiment.

Fig. 3 shows according to the structural representation of the overcurrent protective device of an embodiment of the present utility model.

As shown in Figure 3, according to the overcurrent protective device of an embodiment of the present utility model, comprise: comparison circuit 300, be connected to the current sample element in Intelligent Power Module 100, for the real-time voltage analog signal from described current sample element and normal voltage analog signal are carried out to numeric ratio, and generate corresponding analog control signal according to comparative result; Integrated circuit 400, be connected to described comparison circuit 300 and corresponding to the controller 200 of described Intelligent Power Module 100, for the simulated timing diagrams signal from described controller 200 and described analog control signal are integrated, and export the simulated timing diagrams signal after integrating to described Intelligent Power Module 100.

For convenience of explanation; current sampling circuit is wherein shown in Fig. 3 with concrete sampling resistor 138; and those skilled in the art should understand that be; sampling resistor 138 is only preferred embodiment a kind of; obviously also can realize the current sample to Intelligent Power Module 100 by other elements, and control for overcurrent protection.

Than the overcurrent protection means in the correlation technique shown in Fig. 2, the utility model proposes the processing mode of complete sampled analogue signals, by the collection at current signal, in control procedure when comparison and overcurrent protection, all use analog signal to process, make without carrying out MCU(as controller 200) analog signal in processing procedure and the conversion operations between digital signal, thereby can shorten and from signals collecting to reality, carry out the delay in overcurrent protection control procedure, while avoiding electric current larger, cause Intelligent Power Module 100 to be just damaged within time of delay, effectively promoted the safety in utilization of Intelligent Power Module 100, eliminated potential safety hazard.

Simultaneously; owing to adopting the sampling of analog signal, the processing procedure such as relatively; make it possible at any time the current conditions on current sample element (as sampling resistor 138) be fed back; accomplish real-time overcurrent protection, avoid as much as possible fortuitous event to cause Intelligent Power Module 100 that security incident occurs.

It should be noted that, current sample element is the indeclinable element of resistance generally, such as resistance, for the current conditions on current sample element, be actually and feed back by change in voltage, thereby be actually by the comparison to real-time voltage analog signal and normal voltage analog signal, to determine whether to occur overcurrent condition.

For 300 pairs of comparison circuits, from the real-time voltage analog signal of sampling resistor 138 and the comparison procedure of normal voltage analog signal, can process based on following logic:

In the situation that described real-time voltage analog signal is more than or equal to described normal voltage analog signal, described analog control signal is the first analog control signal, and the simulated timing diagrams signal after described integration is low level signal; And

In the situation that described real-time voltage analog signal is less than described normal voltage analog signal, described analog control signal is the second analog control signal, and the simulated timing diagrams signal after described integration is identical with the simulated timing diagrams signal from described controller.

In this technical scheme, when there is overcurrent condition, to cause real-time voltage analog signal to be more than or equal to normal voltage analog signal, the What gives of the simulated timing diagrams signal of controller 200 outputs no matter now, all directly to all of the port input low level signal of Intelligent Power Module 100, all IGBT pipes (IGBT pipe 121 as shown in Figure 1 etc.) are all quit work, thereby can realize overcurrent protection fast; And when not there is not overcurrent condition, real-time voltage analog signal is less than normal voltage analog signal, by making simulated timing diagrams signal constant before and after integrating, thereby guarantee can not impact the course of normal operation of Intelligent Power Module 100.

In the technical scheme shown in Fig. 3, for convenience of explanation, only broadly show 400 pairs of analog control signals from comparison circuit 300 of integrated circuit and the integration processing procedure of carrying out the simulated timing diagrams signal of self-controller 200; Yet, controller 200 is when carrying out sequencing control to Intelligent Power Module 100, be actually the control to the on off state of each the IGBT pipe in Intelligent Power Module 100 by many circuits, thereby in fact integrated circuit 400 comprises a plurality of electronic circuits that correspond respectively to every circuit.

Particularly, Fig. 4 shows according to the structural representation of the overcurrent protective device of another embodiment of the present utility model.

As shown in Figure 4, for every between controller 200 and Intelligent Power Module 100 corresponding sequencing control circuit, in fact integrated circuit 400 has comprised one by one a plurality of integron circuit 400 ' corresponding to a plurality of output ports of controller 200 and a plurality of input ports of Intelligent Power Module 100, wherein, described in each, integron circuit 400 ' comprising:

First input end, is connected to the default output port of described controller 200, for receiving corresponding simulated timing diagrams signal; The second input, is connected to described comparison circuit 300, for receiving described analog control signal; Output, be connected to the default input port of described Intelligent Power Module 100, be used in the situation that analog control signal is the first above-mentioned analog control signal, output low level signal, and in the situation that analog control signal is the second above-mentioned analog control signal, export described simulated timing diagrams signal.

In this technical scheme; corresponding to each the IGBT pipe in Intelligent Power Module 100; controller 200 all needs to input corresponding simulated timing diagrams signal by corresponding pin; can to the simulated timing diagrams signal of respective pin, process by each integron circuit 400 ', thereby realize, the overcurrent protection of all IGBT pipes be controlled.

Based on foregoing description; what those skilled in the art can understand is; the utility model proposes a kind of new overcurrent protective device; the curent change making it possible to based on Intelligent Power Module 100 carries out fast reaction; within as far as possible little time of delay; realization is controlled and is processed the overcurrent protection of Intelligent Power Module 100, reduces the risk that Intelligent Power Module 100 breaks down, damages.

So, Fig. 5 correspondingly shows in a kind of comparatively specific embodiment, includes the concrete structure schematic diagram of the Intelligent Power Module of above-mentioned overcurrent protective device.

As shown in Figure 5; according in the Intelligent Power Module 4100 of an embodiment of the present utility model; by being provided with overcurrent protective device 4201, realized the high-speed switch of all IGBT pipes has been controlled, realized the overcurrent protection fast of Intelligent Power Module 4100 has been controlled.

Wherein, the concrete line construction of above-mentioned Intelligent Power Module 4100 comprises:

The power positive end VCC end of the power positive end VV end of overcurrent protective device 4201 and drive circuit (or driving chip) 4101 is as the low-pressure area power supply anode VDD of described Intelligent Power Module 4100, and VDD is generally 15V.

The first input end IN1 of described overcurrent protective device 4201 goes up brachium pontis input UHIN mutually as the U of described Intelligent Power Module 4100; The second input IN2 of described overcurrent protective device 4201 goes up brachium pontis input VHIN mutually as the V of described Intelligent Power Module 4100; The 3rd input IN3 of described overcurrent protective device 4201 goes up brachium pontis input WHIN mutually as the W of described Intelligent Power Module 4100; The four-input terminal IN4 of described overcurrent protective device 4201 descends brachium pontis input ULIN mutually as the U of described Intelligent Power Module 4100; The 5th input IN5 of described overcurrent protective device 4201 descends brachium pontis input VLIN mutually as the V of described Intelligent Power Module 4100; The 6th input IN6 of described overcurrent protective device 4201 descends brachium pontis input WLIN mutually as the W of described Intelligent Power Module 4100.

The first output OUT1 of described overcurrent protective device 4201 connects the HIN1 end of described drive circuit 4101; The second output OUT2 of described overcurrent protective device 4201 connects the HIN2 end of described drive circuit 4101; The 3rd output OUT3 of described overcurrent protective device 4201 connects the HIN3 end of described drive circuit 4101; The 4th output OUT4 of described overcurrent protective device 4201 connects the LIN1 end of described drive circuit 4101; The 5th output OUT5 of described overcurrent protective device 4201 connects the LIN2 end of described drive circuit 4101; The 6th output OUT6 of described overcurrent protective device 4201 connects the LIN3 end of described drive circuit 4101; The 7th output TT of described overcurrent protective device 4201 is as the abnormal feedback end TR of described Intelligent Power Module 4100.

The power supply negative terminal GG of overcurrent protective device 4201 and the GND of described drive circuit 4101 end are as the minimum voltage reference point N of described Intelligent Power Module 4100.

In described drive circuit 4101 inside, have boostrap circuit, boostrap circuit structure is as follows: VCC end is connected with the anode of bootstrap diode 4101A, bootstrap diode 4101B, bootstrap diode 4101C; The negative electrode of described bootstrap diode 4101A is connected with VB1; The negative electrode of described bootstrap diode 4101B is connected with VB2; The negative electrode of described bootstrap diode 4101C is connected with VB3; At this, the U of described Intelligent Power Module 4100, V, the input of W three-phase Liu road receive the input signal of 0V or 5V.

The VB1 end of described drive circuit 4101 connects one end of electric capacity 131, and as the U phase higher-pressure region power supply anode UVB of described Intelligent Power Module 4100; The grid that HO1 end and the U of described drive circuit 4101 goes up brachium pontis IGBT pipe 4121 is mutually connected; , anode, the U of FRD pipe 4111 descend mutually, the collector electrode of brachium pontis IGBT pipe 4124, FRD manage 4114 negative electrode to the emitter-base bandgap grading of the VS1 end of described drive circuit 4101 and described IGBT pipe 4121, the other end of described electric capacity 4131 is connected, and as the U phase higher-pressure region power supply negative terminal UVS of described Intelligent Power Module 4100.

The VB2 end of described drive circuit 4101 connects one end of electric capacity 4132, as the U phase higher-pressure region power supply anode VVB of described Intelligent Power Module 4100; The grid that HO3 end and the V of described drive circuit 4101 goes up brachium pontis IGBT pipe 4123 is mutually connected; , anode, the V of FRD pipe 4112 descend mutually, the collector electrode of brachium pontis IGBT pipe 4125, FRD manage 4115 negative electrode to the emitter-base bandgap grading of the VS2 end of described drive circuit 4101 and described IGBT pipe 4122, the other end of described electric capacity 4132 is connected, and as the W phase higher-pressure region power supply negative terminal VVS of described Intelligent Power Module 4100.

The VB3 end of described drive circuit 4101 connects one end of electric capacity 4133, as the W phase higher-pressure region power supply anode WVB of described Intelligent Power Module 4100; The grid that HO3 end and the W of described drive circuit 4101 goes up brachium pontis IGBT pipe 4123 is mutually connected; , anode, the W of FRD pipe 4113 descend mutually, the collector electrode of brachium pontis IGBT pipe 4126, FRD manage 4116 negative electrode to the emitter-base bandgap grading of the VS3 end of described drive circuit 4101 and described IGBT pipe 4123, the other end of described electric capacity 4133 is connected, and as the W phase higher-pressure region power supply negative terminal WVS of described Intelligent Power Module 4100.

The LO1 end of described drive circuit 4101 is connected with the grid of described IGBT pipe 4124; The LO2 end of described drive circuit 4101 is connected with the grid of described IGBT pipe 4125; The LO3 end of described drive circuit 4101 is connected with the grid of described IGBT pipe 4126.

The anode of the emitter-base bandgap grading of the anode of the emitter-base bandgap grading of the anode of the emitter-base bandgap grading of described IGBT pipe 4124, described FRD pipe 4114, described IGBT pipe 4125 and described FRD pipe 4115, described IGBT pipe 4126, described FRD pipe 116 is connected, and contact resistance 4301(is equivalent to the sampling resistor 138 shown in Fig. 3) one end and the 7th input RS of described overcurrent protective device 4201; The other end of described resistance 4301 connects the minimum voltage reference point N of described Intelligent Power Module 4100.

The negative electrode of the collector electrode of the negative electrode of the collector electrode of the negative electrode of the collector electrode of described IGBT pipe 4121, described FRD pipe 4111, described IGBT pipe 4122, described FRD pipe 4112, described IGBT pipe 4123, described FRD pipe 4113 is connected, and as the high voltage input P of described Intelligent Power Module 4100, P generally meets 300V.

The 7th output TT of described overcurrent protective device 4201 is as the TR end of described Intelligent Power Module 4100.

Based on above-mentioned annexation, the process that the concrete execution overcurrent of overcurrent protective device 4201 comprises comprises:

1, first constantly

Suppose that the voltage at resistance 4301 two ends is lower than default standard voltage value VT, the control logic for the clock signal of input driving circuit 4101 is: make all output signals of overcurrent protective device 4201 all consistent with corresponding input signal.

Particularly, the processing logic that each port is corresponding comprises:

The signal of the signal of the first output OUT1 of overcurrent protective device 4201 and the first input end IN1 of described overcurrent protective device 4201 is consistent; The signal of the signal of the second output OUT2 of described overcurrent protective device 4201 and the second input IN2 of described overcurrent protective device 4201 is consistent; The signal of the signal of the 3rd output OUT3 of described overcurrent protective device 4201 and the 3rd input IN3 of described overcurrent protective device 4201 is consistent; The signal of the signal of the 4th output OUT4 of described overcurrent protective device 4201 and the four-input terminal IN4 of described overcurrent protective device 4201 is consistent; The signal of the signal of the 5th output OUT5 of described overcurrent protective device 4201 and the 5th input IN5 of described overcurrent protective device 4201 is consistent; The signal of the signal of the 6th output OUT6 of described overcurrent protective device 4201 and the 6th input IN6 of described overcurrent protective device 4201 is consistent.

2, second constantly

Suppose that the voltage at resistance 4301 two ends is higher than default standard voltage value VT, the control logic for the clock signal of input driving circuit 4101 is: no matter the sequential of input how, all makes all output signals of overcurrent protective device 4201, be low level.

Particularly, the processing logic that each port is corresponding comprises:

The signal of the first output OUT1 of described overcurrent protective device 4201, the second output OUT2, the 3rd output OUT3, the 4th output OUT4, the 5th output OUT5, the 6th output OUT6 keeps low level, and irrelevant with the signal of IN1～IN6.

At this; although in Fig. 5; overcurrent protective device 4201 and drive circuit 4101 are drawn as to two different unit; but those skilled in the art should understand that: the function of overcurrent protective device 4201 and drive circuit 4101 can realize by same flow platform completely in a wafer; thereby practical function is integrated, be convenient to control the volume of Intelligent Power Module 4100.

And in order to realize the function of the comparison circuit 300 shown in above-mentioned overcurrent protective device 4201 or Fig. 3, Fig. 4, integrated circuit 400 etc., especially by the processing mode of analog signal, below in conjunction with Fig. 6, its concrete circuit structure is elaborated.

Fig. 6 shows the concrete structure schematic diagram according to the overcurrent protective device of an embodiment of the present utility model.

As shown in Figure 6, as a kind of comparatively concrete execution mode, comparison circuit 300 can comprise: comparator 4214, and the positive input terminal access normal voltage analog signal of comparator 4214, negative input end access real-time voltage analog signal, and output is connected to integrated circuit 400.

In this technical scheme, processing procedure for mating die analog signal, can adopt as comparator 4214 and realize real-time voltage analog signal and normal voltage analog signal are compared, thereby can carry out fast whether the judgement of overcurrent condition occurring, and make accordingly corresponding processing.

As a kind of comparatively concrete execution mode, it is low level signal, described the second analog control signal be high level signal in the situation that Fig. 6 shows at described the first analog control signal, the concrete structure of integrated circuit 400.Wherein, for a concrete integron circuit 400 ', for example describes, this integron circuit 400 ' can comprise:

NAND gate 4202, two inputs of described NAND gate 4202 are connected to respectively described first input end and described the second input; Or door 4203, input described or door 4203 is connected to the output of described NAND gate 4202, and output described or door 4203 is connected to the output of the integron circuit 400 ' that comprises described or door 4203.

In this technical scheme; as a kind of comparatively preferred embodiment; can adopt concrete gate circuit to realize processes the integration of simulated timing diagrams signal; thereby by logical process processes such as the quick comparison of analog signal, integration, realize the overcurrent protection fast and accurately to Intelligent Power Module 4100.

Simultaneously; the NM technical problem of foregoing is: Intelligent Power Module 4100 in the course of the work; may cause temperature to raise; and and then change sampling resistor 4301(when Intelligent Power Module 100 corresponding in Fig. 3 and Fig. 4; be specially sampling resistor 138) resistance; thereby make the numerical value of the real-time voltage analog signal that comparison circuit 300 obtains bigger than normal; and may cause being judged as by mistake and need to carry out overcurrent protection to Intelligent Power Module 4100, affect the normal work of Intelligent Power Module 4100.

In order to solve the problems of the technologies described above, preferably, for comparative standard voltage analog signal, it should not a fixing voltage value, and should with sampling resistor 4301 consistently, variations in temperature with Intelligent Power Module 4100 changes, thereby make, under any temperature regime, between real-time voltage analog signal and normal voltage analog signal, all to match.

So; according to another embodiment of the present utility model; preferably; above-mentioned overcurrent protective device 4201 also comprises: signal generating circuit; be connected to described comparison circuit 300 and described Intelligent Power Module 4100; for responding to the real time temperature situation of described Intelligent Power Module 4100; and generate described normal voltage analog signal according to described real time temperature situation; wherein, the numerical values recited of described real-time voltage analog signal and described normal voltage analog signal consistently changes with the variation of described real time temperature situation.

In this technical scheme, because variations in temperature may cause the resistance of current sample element, change, and while making to carry out according to normal overcurrent protection logic, may cause that erroneous judgement occurs disconnected.Therefore, by the induction of the real time temperature situation to Intelligent Power Module 4100, can make the logic of overcurrent protection to change with the variations in temperature of Intelligent Power Module 4100, avoid judging by accident disconnected generation.

Preferably, the numerical values recited of described real-time voltage analog signal and described normal voltage analog signal is all proportionate with described real time temperature situation.

In this technical scheme, when voltage swing and real time temperature situation are proportionate, when the temperature of Intelligent Power Module raises, will cause the numerical value of real-time voltage analog signal to increase; And by the numerical value of normal voltage analog signal is increased, thereby can avoid the disconnected normal operating conditions that causes affecting Intelligent Power Module of erroneous judgement.

Preferably, described signal generating circuit comprises: the first DC power supply; The first temperature sensitive member, one end of described the first temperature sensitive member is connected to the positive pole of described the first DC power supply and described comparison circuit, the other end and described Intelligent Power Module altogether.

During corresponding to embodiment shown in Fig. 6, the first DC power supply is that current source 4217, the first temperature sensitive member are resistance 4216.So, by current source 4217 and resistance 4216, realize the generation to normal voltage analog signal, and make the normal voltage analog signal of resistance 4216 correspondences to raise and to increase with the temperature of Intelligent Power Module 4100, to be adapted to the variation of real-time voltage analog signal.

In this technical scheme, as a kind of comparatively concrete execution mode, the temperature sensitive member of (being herein altogether) can be connected with Intelligent Power Module by adopting, the induction of realization to the real time temperature situation of Intelligent Power Module, especially the Intelligent Power Module in correlation technique in the course of the work, overall work uniformity of temperature profile, thereby can come the working temperature of Intelligent Power Module to realize induction exactly by above-mentioned temperature sensitive member.

Particularly, because the current value of the first DC power supply is constant, while causing the change in resistance of the first temperature sensitive member when variations in temperature, variations in temperature may be embodied on the voltage value of the first temperature sensitive member input comparison circuit.

The 7th output TT of described overcurrent protective device 4201 is a voltage relevant to the bulk temperature of described Intelligent Power Module 4100 of output in real time; this signal can connect the control devices such as MCU, allow Intelligent Power Module 4100 described in these control device perception real time temperature and make respective handling.

Corresponding to the embodiment shown in Fig. 6, Fig. 7 shows the concrete structure schematic diagram according to the overcurrent protective device of another embodiment of the present utility model.

As shown in Figure 7; on basis embodiment illustrated in fig. 6; overcurrent protective device can also comprise: temperature regime output circuit; be connected to described Intelligent Power Module 4100 and described controller (not shown), for exporting the circuit characteristic parameter information of the real time temperature situation corresponding to described Intelligent Power Module 4100 to described controller.

In this technical scheme, because no longer carrying out current control to Intelligent Power Module 4100, controller controlled, also cannot carry out the temperature detection to Intelligent Power Module 4100, thereby by exporting the real time temperature situation of Intelligent Power Module 4100 to controller, make controller can realize accordingly more control function.Particularly, as a kind of comparatively preferred embodiment, such as controller can be according to the real time temperature situation of Intelligent Power Module 4100, control the operating frequency of Intelligent Power Module 4100; Further, when real time temperature is higher, can reduce the operating frequency of Intelligent Power Module 4100, when real time temperature is lower, the operating frequency of the Intelligent Power Module that can raise 4100.

Preferably, described temperature regime output circuit comprises: the second DC power supply; The second temperature sensitive member, one end of described the second temperature sensitive member is connected to the positive pole of described the second DC power supply and described controller, the other end and described Intelligent Power Module altogether.Wherein, corresponding to the embodiment shown in Fig. 7, the second DC power supply is that current source 4218, the second temperature sensitive member are resistance 4215.

In this technical scheme, as a kind of comparatively specific embodiment, can to Intelligent Power Module 4100, carry out temperature sense by temperature sensitive member, the working temperature due to Intelligent Power Module 4100 is evenly distributed, thereby can realize the accurate detection to Intelligent Power Module 4100 by temperature sensitive member.

Particularly, because the current value of the second DC power supply is constant, while causing the change in resistance of the second temperature sensitive member when variations in temperature, variations in temperature may be embodied on the voltage value of the second temperature sensitive member input control device.

More specifically, the annexation of each parts in the circuit shown in Fig. 7 comprises:

The first input end IN1 of overcurrent protective device 4201 is connected with one of them input of NAND gate 4202; The second input IN2 of overcurrent protective device 4201 is connected with one of them input of NAND gate 4204; The 3rd input IN3 of overcurrent protective device 4201 is connected with one of them input of NAND gate 4206; The four-input terminal IN4 of overcurrent protective device 4201 is connected with one of them input of NAND gate 4208; The 5th input IN5 of overcurrent protective device 4201 is connected with one of them input of NAND gate 4201; The 6th input IN6 of overcurrent protective device 4201 is connected with one of them input of NAND gate 4212.

The input of the output NAND gate 4203 of described NAND gate 4202 is connected; The input of the output NAND gate 4205 of described NAND gate 4204 is connected; The input of the output NAND gate 4207 of described NAND gate 4206 is connected; The input of the output NAND gate 4209 of described NAND gate 4208 is connected; The input of the output NAND gate 4211 of described NAND gate 4201 is connected; The input of the output NAND gate 4213 of described NAND gate 4212 is connected.

The output of described not gate 4203 is connected with the first output OUT1 of overcurrent protective device 4201; The output of described not gate 4205 is connected with the second output OUT2 of overcurrent protective device 4201; The output of described not gate 4207 is connected with the 3rd output OUT3 of overcurrent protective device 4201; The output of described not gate 4209 is connected with the 4th output OUT4 of overcurrent protective device 4201; The output of described not gate 4211 is connected with the 5th output OUT5 of overcurrent protective device 4201; The output of described not gate 4213 is connected with the 6th output OUT6 of overcurrent protective device 4201.

The power positive end VV end of overcurrent protective device 4201 is powered with giving current source 4217 and current source 4218; The current output terminal of described current source 4217 is connected with the positive input terminal of comparator 4214 with one end of resistance 4216; The current output terminal of described current source 4218 is connected with one end of resistance 4215 and as overcurrent protective device 4201 the 7th output TT; The other end of the other end of described resistance 4216 and described resistance 4215 is connected and meets the power supply negative terminal GG of overcurrent protective device 4201.

Based on said structure, the operation principle of the present embodiment is described below:

1, element value

Described resistance 4216 is the resistance of a positive temperature coefficient, because the bulk temperature of Intelligent Power Module 4100 when working distributes substantially even, the temperature difference that makes to be positioned at the components and parts of Intelligent Power Module 4100 main bodys generally can not surpass 2 ℃, thereby the temperature of the temperature of resistance 4216 and resistance 4301 is basically identical.

Wherein, resistance 4216 should be chosen the resistance of positive temperature coefficient, the Intelligent Power Module that is 10A for current capacity, 10m Ω when described resistance 4301 can value be normal temperature, temperature coefficient is made as TCR1,100k Ω when described resistance 4216 can value be normal temperature, temperature coefficient is made as TCR2, described current source 4217 is 1 μ A, when normal temperature

The pressure drop Vp of the anode of described comparator 4214 is:

Vp＝1μA×100kΩ＝0.1V；

The pressure drop Vn of the negative terminal of described comparator 4214 is:

Vn=I _rS* 10k Ω, wherein, I _rSfor flowing through the current value of described resistance 4301.

So, work as I _rSduring <10A, Vn<Vp, described comparator 4214 output high level, work as I _rSduring >10A, Vn>Vp, described comparator 4214 output low levels.

When variations in temperature Δ T, the resistance of described resistance 4301 becomes (TCR1 Δ T+1) * 10m Ω, and the resistance of described resistance 4216 becomes (TCR2 Δ T+1) * 100k Ω, makes must keep triggering the electric current I that described comparator 4214 outputs deflect _rSvalue be that 10A is constant, need meet following relation:

(TCR1·ΔT+1)×10mΩ×10A=(TCR2·ΔT+1)×100kΩ×1μA

Be TCR2=TCR1.

Therefore,, when choosing described resistance 4216, should make its temperature coefficient and described resistance 4301 be consistent as far as possible.

2, processing logic

Based on foregoing description, concrete logic can be expressed as:

Work as I _rSduring <10A, described comparator 4214 output high level, described NAND gate 4202, described NAND gate 4204, described NAND gate 4206, described NAND gate 4208, described NAND gate 4201, the level of described NAND gate 4212 outputs respectively with IN1, IN2, IN3, IN4, IN5, IN6 is anti-phase, pass through respectively described not gate 4203, described not gate 4205, described not gate 4207, described not gate 4209, described not gate 4211, after described not gate 4213, respectively at OU1, OUT2, OUT3, OUT4, OUT5, OUT6 output and IN1, IN2, IN3, IN4, IN5, the signal of IN6 homophase, that is:

Within the scope of total temperature, work as I _rSduring <10A, the signal of OUT1 is consistent with the signal of IN1, the signal of OUT2 and the signal of IN2 consistent, the signal of OUT3 is consistent with the signal of IN3, the signal of OUT4 and the signal of IN4 unanimously, the signal of OUT5 and the signal of IN6 consistent.

Work as I _rSduring >10A, described comparator 4214 output low levels, described NAND gate 4202, described NAND gate 4204, described NAND gate 4206, described NAND gate 4208, described NAND gate 4201, described NAND gate 4212 output high level, respectively after described not gate 4203, described not gate 4205, described not gate 4207, described not gate 4209, described not gate 4211, described not gate 4213, in OU1, OUT2, OUT3, OUT4, OUT5, OUT6 output low level, that is:

Within the scope of total temperature, work as I _rSduring >10A, OU1, OUT2, OUT3, OUT4, OUT5, OUT6 keep low level.

Because comparator 4214 is to compare in real time the voltage of its positive input terminal and negative input end; for general BCD technique or CMOS technique; its time delay can not surpass 5ns; signal almost can be ignored through NAND gate and non-time delay behind the door; therefore, when flowing through the electric current of described resistance 4301, occur when abnormal, can be at 5ns time internal cutting off input signal; the overcurrent protection scheme that is obviously better than adopting controller, has very strong real-time.

3, temperature feedback

Resistance 4215 is the thermistor of a negative temperature coefficient, be NTC, current popular Thinking on the market, TDK, the NTC such as field, village, in 25 ℃～125 ℃, its temperature coefficient substantially constant, be designated as TCR3, its variable quantity generally can accomplish to be less than 1%, value about described resistance 4215, can consider to choose 25 ℃ for the resistance of 100k Ω, described current source 4218 can consider to be designed to 1 μ A, in the time of 25 ℃, the power that electric current flows through described resistance 4215 is 100nW, its caloric value can be ignored, the heating with described Intelligent Power Module 4100 of the variations in temperature of described resistance 4215 own is relevant.If variations in temperature is Δ T ', the TR of described Intelligent Power Module 4100 end, the voltage VTT of the TT of overcurrent protective device 4201 end is:

VTT=1 μ A * (TCR3 Δ T '+1) * 100k Ω=0.1 * (TCR3 Δ T '+1), wherein, TCR3 is a negative value.

Visible, the variation of VTT and Δ T ' are linear.This voltage signal VTT is real-time transmitted to MCU, MCU can be by detecting the change in voltage of VTT, obtain the actual work temperature of described Intelligent Power Module 4100, MUC can suitably adjust the operating state of described Intelligent Power Module 4100 according to the height of temperature if needed.

Certainly, adopting resistance to carry out temperature sense is a kind of concrete execution mode, it will be understood by those skilled in the art that obviously and can realize by the components and parts of a lot of other types the function of temperature sense.Particularly, such as Fig. 8 shows the concrete structure schematic diagram according to the overcurrent protective device of another embodiment of the present utility model.

As shown in Figure 8, than the embodiment shown in Fig. 7, changed resistance 4215 into NPN pipe 4219.The base stage of NPN pipe 4219 is connected with collector electrode and connects current source 4218, and the emitter of NPN pipe 4219 meets the power supply negative terminal GG of overcurrent protective device 4201.

Wherein, described current source 4218 can be designed to 100 μ A, and according to the temperature characterisitic of NPN pipe self PN junction, the voltage VTT of the TT end of overcurrent protective device 4201 is :-1.5mV/ ℃.

Meanwhile, although do not specifically illustrate in Figure of description, the utility model has also proposed a kind of Intelligent Power Module, comprises the overcurrent protective device as described in any one in technique scheme.

Similarly, the utility model has also proposed a kind of frequency-conversion domestic electric appliances, comprises above-mentioned Intelligent Power Module.

More than be described with reference to the accompanying drawings the technical solution of the utility model; consider in correlation technique; when controller is controlled the overcurrent protection of Intelligent Power Module in execution; there is long situation time of delay; thereby the utility model proposes a kind of overcurrent protective device, a kind of Intelligent Power Module and a kind of frequency-conversion domestic electric appliances; can disturb in Intelligent Power Module, block cylinder, voltage collapse etc. when abnormal, more promptly realize overcurrent protection, the potential safety hazard of avoiding control lag to cause.

The foregoing is only preferred embodiment of the present utility model, be not limited to the utility model, for a person skilled in the art, the utility model can have various modifications and variations.All within spirit of the present utility model and principle, any modification of doing, be equal to replacement, improvement etc., within all should being included in protection range of the present utility model.

Claims (10)

1. an overcurrent protective device, is characterized in that, comprising:

Comparison circuit, is connected to the current sample element in Intelligent Power Module, for the real-time voltage analog signal from described current sample element and normal voltage analog signal are carried out to numeric ratio, and generates corresponding analog control signal according to comparative result;

Integrated circuit, be connected to described comparison circuit and corresponding to the controller of described Intelligent Power Module, for the simulated timing diagrams signal from described controller and described analog control signal are integrated, and export the simulated timing diagrams signal after integrating to described Intelligent Power Module.

2. overcurrent protective device according to claim 1, is characterized in that, described comparison circuit comprises:

Comparator, the positive input terminal of described comparator accesses described normal voltage analog signal, negative input end accesses described real-time voltage analog signal, and output is connected to described integrated circuit.

3. overcurrent protective device according to claim 1; it is characterized in that, described integrated circuit comprises a plurality of identical integron circuit, one by one corresponding to a plurality of output ports of described controller and a plurality of input ports of described Intelligent Power Module; wherein, described in each, integron circuit comprises:

First input end, is connected to the default output port of described controller, for receiving corresponding simulated timing diagrams signal;

The second input, is connected to described comparison circuit, for receiving described analog control signal;

Output, be connected to the default input port of described Intelligent Power Module, in the situation that described analog control signal is high level signal, export described simulated timing diagrams signal, and in the situation that described analog control signal is low level signal, output low level signal.

4. overcurrent protective device according to claim 3, is characterized in that, described in each, integron circuit comprises:

NAND gate, two inputs of described NAND gate are connected to respectively described first input end and described the second input;

Or door, input described or door is connected to the output of described NAND gate, and output described or door is connected to the output of the integron circuit that comprises described or door.

5. according to the overcurrent protective device described in any one in claim 1 to 4, it is characterized in that, also comprise:

Signal generating circuit, is connected to described comparison circuit and described Intelligent Power Module, for responding to the real time temperature situation of described Intelligent Power Module, and generates described normal voltage analog signal according to described real time temperature situation.

6. overcurrent protective device according to claim 5, is characterized in that, described signal generating circuit comprises:

The first DC power supply;

The first temperature sensitive member, one end of described the first temperature sensitive member is connected to the positive pole of described the first DC power supply and described comparison circuit, the other end and described Intelligent Power Module altogether.

7. overcurrent protective device according to claim 5, is characterized in that, also comprises:

Temperature regime output circuit, is connected to described Intelligent Power Module and described controller, for exporting the circuit characteristic parameter information of the real time temperature situation corresponding to described Intelligent Power Module to described controller.

8. overcurrent protective device according to claim 7, is characterized in that, described temperature regime output circuit comprises:

The second DC power supply;

The second temperature sensitive member, one end of described the second temperature sensitive member is connected to the positive pole of described the second DC power supply and described controller, the other end and described Intelligent Power Module altogether.

9. an Intelligent Power Module, is characterized in that, comprises the overcurrent protective device as described in any one in claim 1 to 8.

10. a frequency-conversion domestic electric appliances, is characterized in that, comprises Intelligent Power Module as claimed in claim 9.