JP7343180B2 - Electrical element testing equipment - Google Patents

Description

The present invention relates to power cycle testing of semiconductor devices such as SiC, IGBT, MOS-FET, Gan-FET, bipolar transistor, posistor, thermistor, etc., and an electric device testing apparatus for testing and evaluating electronic devices and electric devices. It relates to testing methods, evaluation methods, etc. of electrical devices.

To provide a semiconductor device testing device and a semiconductor device testing method that can efficiently reproduce stress similar to a failure mode in the usage environment of a semiconductor device and can evaluate a power semiconductor device or the like with high reliability.

The lifespan of a power semiconductor element includes a lifespan due to a thermal fatigue phenomenon caused by heat generation of the power semiconductor element itself, and a lifespan due to a thermal fatigue phenomenon caused by temperature changes in the external environment of the power semiconductor element. In addition, there is a lifespan due to voltage fatigue due to the voltage applied to the gate insulating film of the power semiconductor element.

In general, a life test of a power semiconductor element is performed by repeatedly turning on and off electricity to the semiconductor element. For example, test by setting the applied voltage and current to the emitter terminal (source terminal), collector terminal (drain terminal), etc. of a transistor of a semiconductor device, and applying a periodic on/off signal (operation/non-operation signal) to the gate terminal. will be held.

The current applied to semiconductor elements during testing is large, several hundred amperes, and low resistance wiring is required to avoid heat generation and voltage drop. Since the test current is large, it is necessary to connect the terminals of the semiconductor element with low resistance. Furthermore, there are many types of tests, and it is necessary to change the connection of the connection wiring in a short time to correspond to the type of test.

JP2014-138488

In a conventional semiconductor device testing apparatus, a power semiconductor device (transistor, etc.) is tested by turning the transistor 117 on and off and flowing a constant current Id through the channel of the transistor.

There are a wide variety of test items performed by a semiconductor device testing device (power cycle testing device), and it is necessary to change the connection to the transistor 117 in accordance with the test items.

The constant current Id is often a current of several hundred A or more, and it is necessary to use thick wires for the connection wiring 211 and the power supply wiring 212 through which the current flows. Further, a large current Id flows through the element terminal 226 of the semiconductor element. When there is contact resistance between the semiconductor element terminal and the connection wiring, there is a problem that the contact portion generates heat, and the semiconductor element 117 is destroyed due to the heat generation, or the connection portion is burnt out.

The semiconductor device testing apparatus of the present invention includes a connection structure 218 that connects to the device terminal 226 of the semiconductor device to be tested. One end of the connection structure 218 has a connection part (connection receiving part 225, connection pressure part 232, connection holding part 233) that contacts the element terminal 226, and a peat pipe 223 is attached to the surface of the connection structure 218. ing. Electrical connection is established by inserting the element terminals 226 of the semiconductor element into the connection portions of the connection structure 218.
By inserting the connection structure 218 into the opening 216 formed in the partition wall 217, electrical connection is established with the element terminal 226 of the semiconductor element 117 to be tested.

The semiconductor device testing device of the present invention includes a location (space) in the semiconductor device testing device in which a transistor 117 to be tested is placed, and a circuit that generates a test current for the transistor 117, generates a control signal, and obtains test results. The location where the board is placed is separated. Partition walls (partition walls 217, 215, and 214) are provided for separation.

The transistor to be tested and the circuit board are connected by inserting the fork plug 205 (connection plug 205) through the opening 216 provided in the partition wall 214, and connecting the connection plug 205 and the conductor plate 204 provided on the circuit board. This is done by contacting the

Since there is contact resistance in the connection between the element terminal 226 of the transistor 117 to be tested and the connection structure 218, the contact generates heat when a large current flows. In the present invention, since the heat pipe 223 is arranged in the connection structure 218, the generated heat can be efficiently conducted and released.

The element terminal 226 is sandwiched between the connection receiving part 225 and the connection pressure part 232, and is electrically connected well. Therefore, the connection portion of the element terminal 226 has no or very small contact resistance, and the element terminal 226 portion generates almost no heat.

Since the element terminal 226 and the connection structure 218 are inserted through the opening 216 of the partition wall 217, they can be easily attached and detached from the transistor 117 to be tested, and the connection to the transistor 117 to be tested can be changed in a short time. can.

A partition wall 214 is provided to separate a location (space) in the semiconductor device testing device where the transistor 117 is placed from a location where the circuit board is placed where the test current for the transistor 117 is generated, the control signal is generated, and the test results are obtained. There is. The connection plug 205 is inserted through the opening 216 provided in the partition wall 214, and the connection plug 205 and the conductor plate 204 provided on the circuit board are connected. There is no need to connect the connection wires 211 for each test item, no work space is required for changing the connection of the wires, and the semiconductor device testing apparatus can be downsized.

FIG. 2 is a configuration diagram and an explanatory diagram of a connection terminal portion of the electric device testing apparatus of the present invention. FIG. 2 is a configuration diagram and an explanatory diagram of a connection terminal portion of the electric device testing apparatus of the present invention. FIG. 2 is a configuration diagram and an explanatory diagram of a connection terminal portion of the electric device testing apparatus of the present invention. FIG. 2 is a configuration diagram and an explanatory diagram of a connection terminal portion of the electric device testing apparatus of the present invention. FIG. 2 is a configuration diagram and an explanatory diagram of a connection terminal portion of the electric device testing apparatus of the present invention. FIG. 2 is a configuration diagram and an explanatory diagram of a connection terminal portion of the electric device testing apparatus of the present invention. FIG. 2 is a configuration diagram and an explanatory diagram of a connection terminal portion of the electric device testing apparatus of the present invention. FIG. 2 is a configuration diagram and an explanatory diagram of a connection terminal portion of the electric device testing apparatus of the present invention. FIG. 2 is a configuration diagram and an explanatory diagram of a connection terminal portion of the electric device testing apparatus of the present invention. FIG. 2 is a configuration diagram and an explanatory diagram of a connection terminal portion of the electric device testing apparatus of the present invention. FIG. 2 is a configuration diagram and an explanatory diagram of a connection terminal portion of the electric device testing apparatus of the present invention. FIG. 2 is a configuration diagram and an explanatory diagram of a connection terminal portion of the electric device testing apparatus of the present invention. 1 is a configuration diagram and an explanatory diagram of an electric device testing apparatus of the present invention. FIG. 1 is a configuration diagram and an explanatory diagram of an electric device testing apparatus of the present invention. FIG. 1 is a configuration diagram and an explanatory diagram of an electric device testing apparatus of the present invention. FIG. 1 is a configuration diagram and an explanatory diagram of an electric device testing apparatus of the present invention. FIG. FIG. 1 is an explanatory diagram of an electric device testing apparatus of the present invention. FIG. 3 is an explanatory diagram of a connection terminal portion and a connection structure of the electric device testing apparatus of the present invention. FIG. 3 is an explanatory diagram of a connection terminal portion and a connection structure of the electric device testing apparatus of the present invention. FIG. 3 is an explanatory diagram of a connection terminal portion and a connection structure of the electric device testing apparatus of the present invention. FIG. 3 is an explanatory diagram of a connection terminal portion and a connection structure of the electric device testing apparatus of the present invention. FIG. 1 is an explanatory diagram of an electric device testing apparatus of the present invention. FIG. 2 is an explanatory diagram of a method of connecting an electric element testing apparatus and an electric element according to the present invention. FIG. 2 is an explanatory diagram of a method of connecting an electric element testing apparatus and an electric element according to the present invention. FIG. 2 is an explanatory diagram of a method for testing an electric element according to the present invention. FIG. 2 is an explanatory diagram of a method for testing an electric element according to the present invention. FIG. 2 is an explanatory diagram of a method for testing an electric element according to the present invention. FIG. 2 is an explanatory diagram of a method for testing an electric element according to the present invention. FIG. 2 is an explanatory diagram of a method for testing an electric element according to the present invention. FIG. 3 is a timing chart diagram in the method of testing an electric element according to the present invention. FIG. 3 is a timing chart diagram in the method of testing an electric element according to the present invention. FIG. 3 is a timing chart diagram in the method of testing an electric element according to the present invention. FIG. 3 is a timing chart diagram in the method of testing an electric element according to the present invention. FIG. 1 is an explanatory diagram of an electric device testing apparatus of the present invention. FIG. 1 is an explanatory diagram of an electric device testing apparatus of the present invention. FIG. 1 is an explanatory diagram of an electric device testing apparatus of the present invention. FIG. 1 is a configuration diagram of an electric device testing apparatus of the present invention. FIG. 2 is a structural diagram and an equivalent circuit diagram of a semiconductor element. FIG. 2 is a structural diagram and an equivalent circuit diagram of a semiconductor element. FIG. 3 is an explanatory diagram of an electric element.

EMBODIMENT OF THE INVENTION Hereinafter, with reference to the attached drawings, an electric element testing apparatus such as a power cycle test and an electric element testing method according to an embodiment of the present invention will be described.

In the embodiments described in the specification, an IGBT among power semiconductor devices will be described as an example. The present invention is not limited to IGBTs, but can be applied to various power semiconductor devices such as SiC, MOSFETs, JFETs, and transistors. Further, the present invention is not only applicable to transistors, but also to two-terminal elements such as diodes.

Furthermore, it goes without saying that the present invention is not limited to power semiconductor devices, but can also be applied to low-power semiconductor devices and signal control semiconductor devices. It goes without saying that the invention can also be applied to electrical elements such as resistive elements, capacitors, coils, and crystal oscillators.

In each drawing for explaining the embodiments of the invention, elements having the same function are denoted by the same reference numerals, and the description thereof may be omitted. Furthermore, the embodiments of the present invention can be combined.
It goes without saying that the matters described in this specification and the drawings can be combined in part or in whole.

FIG. 13 is a configuration diagram of a power cycle test device (semiconductor device test device) according to the present invention. The power cycle test device includes a chiller (cooling/warming device) 136 in a housing 210, a heating/cooling plate 134, and a circulating water pipe 135 circulating between the heating/cooling plate 134 and the chiller 136. A transistor 117 as a semiconductor element to be tested is mounted on the heating/cooling plate 134 .

Test conditions are set by changing current Id, gate voltage Vgs, and voltage Vce so that temperature information Tj and temperature information Tc of the transistor 117 to be tested become predetermined values.

Tj is temperature information mainly obtained from a diode or the like that measures the temperature of the transistor 117, and Tc is temperature information obtained from the package temperature of the transistor 117 using a thermocouple or the like.

When the temperature information Tj or the temperature information Tc changes, it is determined that the transistor 117 has deteriorated or its characteristics have changed, and the test of the transistor 117 is stopped, the control method is changed, or the test conditions are changed.

A change in characteristics of the transistor 117 is determined based on a change in temperature information Tj or the like. In addition, changes in characteristics, reliability, and life of the transistor 117 are evaluated based on the time it takes for the voltage Vce to reach a predetermined voltage, the time it takes for the transistor 117 to break down, and the like.

In the following explanation, the temperature information Tj will be mainly exemplified. When the temperature information Tj changes, it is determined that the transistor 117 has deteriorated or its characteristics have changed, and the test of the transistor 117 is stopped or the control method is changed.

Note that although the current applied to or applied to the transistor 117 will be described as a constant current Id, the present invention is not limited to this. Needless to say, Id may be a current that changes at a predetermined period or a predetermined time. Further, it is not limited to current, and may be voltage.

In the semiconductor device testing method of the present invention, changes in the characteristics of the transistor 117, which is a semiconductor device, are determined or judged based on changes in temperature information Tj and the like. Further, changes in characteristics, reliability, and life of the transistor 117 are evaluated based on the time from the time when the voltage Vce reaches a predetermined voltage until the transistor 117 is destroyed.

In the semiconductor testing method of the present invention, external conditions are changed according to deterioration or changes in characteristics of the transistor 117. For example, if the transistor 117 generates heat, the water temperature is lowered. When the water temperature is lowered, the current flowing through the transistor 117 decreases, and the deterioration and characteristic changes of the transistor 117 do not progress. As a result, the life of transistor 117 is extended. Therefore, it is possible to quantitatively measure and judge the life span and reliability characteristics of the transistor 117 with respect to predetermined setting conditions.

By heating or cooling the circulating water of the chiller 136, the temperature of the transistor 117 is maintained at a specified value or a predetermined value. In addition, the temperature of the transistor, etc. is changed periodically in accordance with the test conditions, and the transistor is cooled and heated at a constant rate. Furthermore, the temperature information Tj of the test transistor is measured, and the chiller 136 is controlled so as to maintain the measured temperature information Tj at a constant value.

The chiller 136 is configured to keep the temperature of equipment etc. constant by circulating water and heat medium while controlling their temperature. Although it is mainly used for cooling, it can also be used for heating as well as cooling. It is configured to be able to control various temperatures. Feedback control is performed using temperature information Tc and temperature information Tj.

The control circuit 113 has a function of measuring or obtaining the temperature of the element terminal 226 from a thermocouple attached to the element terminal 226 or its vicinity, and controlling the test to be stopped or interrupted or to issue an alarm if the temperature exceeds a predetermined value. has.

The control rack 131 includes a power supply device 132 that supplies a test current and a test voltage to the transistor 117, and a control circuit 133 that controls the transistor 117 or sets test conditions. In FIG. 1(b), a thermocouple 316 is placed at the element terminal 226. A thermocouple 316 may be placed on a test component such as transistor 117.

Temperature information Tj and the like of the transistor 117 are input to the control circuit 133, and the chiller 136 is controlled based on the temperature information Tj and the like. Alternatively, the chiller 136 is controlled so that the temperature information Tj and the like are set to predetermined values.

In addition, although this specification describes circulating water, it is not limited to water. Ethylene glycol, glycerin, chlorofluorocarbon, etc. may be used, or forced air cooling may be used. The chiller 136 controls the liquid in the circulating water pipe 135 within a range of, for example, a water temperature of -1°C to +100°C and supplies it to the heating/cooling plate 134 of the test unit. The heating and cooling plate 134 has a sufficiently large heat capacity.

Although the heating/cooling plate 134 is used in the above embodiment, the heating plate and the cooling plate may be separate bodies, and heating/cooling may be performed using a heat source/cold source other than the heating/cooling plate.

FIG. 14 is a configuration diagram of a semiconductor device testing apparatus (for example, a power cycle testing apparatus for testing power transistors) according to the first embodiment of the present invention. Further, FIG. 25 is an equivalent circuit diagram or an explanatory diagram of the semiconductor device testing apparatus.

The power supply circuit 121 outputs a large constant current Id for testing the transistor 117. The power supply circuit 121 supplies power (current, voltage) in synchronization with a control signal from the control circuit board 111 (controller 111), and uses the supplied power to supply the load with a set constant current or constant voltage. Drive with. Further, the power supply circuit 121 can set the maximum voltage value to be output.

The switch circuit 124a (SWa) turns on (supply) and off (cuts off) the supply of constant current output from the power supply circuit 121. The switch circuit 124a is set or controlled to be on (outputs constant current) or off (blocks constant current) based on a signal from the control circuit board (controller) 111. Normally, the switch circuit 124a is turned on before starting a test, and is always kept on while testing a semiconductor device.

In FIG. 14, one power supply circuit 121 is illustrated. However, the number of power supply circuits 121 is not limited to one. For example, the semiconductor device testing apparatus of the present invention may include two or more power supply circuits 121. As the number of power supply circuits 121 increases, more diverse current waveforms Id or voltage waveforms can be generated. Multiple currents are easy to superimpose.
Although the embodiment of the present invention will be described as a power supply circuit 121, the power supply circuit 121 is not limited to one that outputs a constant current.

For example, a power supply circuit 121 that can set a maximum voltage is used. For example, it may function to output a predetermined constant current at a set maximum voltage under certain conditions. Further, in the case of outputting a constant current, a configuration is illustrated in which the output terminal voltage can be set to a predetermined maximum voltage. It goes without saying that in the semiconductor device testing apparatus of the present invention, the power supply circuit 121 is not a device that outputs only a constant current, but may be a power supply device that can output voltage and current.

In the embodiments shown in FIG. 14 and the like, the current Id will be described as being generated by the power supply circuit 121, but the current Id can also be realized by adjusting the applied voltage according to the state of the on-resistance of the transistor 117. Therefore, it goes without saying that the semiconductor device testing apparatus of the present invention is not limited to the power supply circuit 121 that outputs current, but may be configured with a power supply that outputs voltage.

The current Id can also be realized by controlling the voltage value of the gate voltage of the transistor 117. In this specification, a description will be given assuming that a predetermined current is applied to the transistor 117 under the control of the power supply circuit 121. However, there is no limitation to this, and it goes without saying that the voltage at the gate terminal g of the transistor 117 and the voltage at the collector terminal c of the transistor 117 may be adjusted or controlled.

In the embodiment of the first semiconductor device testing method of the present invention, for ease of explanation, it is assumed that the constant current Id is generated by the power supply circuit 121. The current Id flowing through the transistor 117 is supplied by operating the power supply circuit 121. The power supply circuit 121 is on/off controlled by a signal from the control circuit board (controller) 111. The operation timing of the device control circuit board 209 is controlled by a control circuit board (controller) 111.

The emitter terminal e of the transistor 117 is grounded (connected to a ground line). A gate driver circuit 113 is connected to a gate terminal g of the transistor 117.

In the sample connection circuit 203, a gate driver circuit 113, a variable resistance circuit 125, a constant current circuit 118, and an operational amplifier (buffer circuit) 116 are arranged or formed. The sample connection circuit 203 is placed separately from the device control circuit board 209 so that it can be placed close to the transistor 117 to be tested.

Although it is preferable that one sample connection circuit 203 is provided for each transistor 117 to be tested, the present invention is not limited to this. A connection circuit 203 may also be arranged.

Sample connection circuit 203 is connected to transistor 117 through connection pin 206 of connector 202 . The gate driver circuit 113 and the gate terminal g of the transistor 117 are arranged so as to have a short distance of 30 mm or less. If the distance between the gate driver circuit 113 and the gate terminal g of the transistor 117 is long, noise etc. will be superimposed on the gate terminal g, causing the transistor 117 to malfunction and directly leading to destruction of the transistor 117.

As shown in FIG. 15, the device control circuit board 209 is placed in the B room of the casing 210 of the semiconductor device testing apparatus. The casing 210 is a frame or an apparatus body in which a power supply device 132, a drive circuit, and a heating/cooling plate 134 of the semiconductor testing apparatus are incorporated. The sample connection circuit 203 is placed in the C1 room of the casing 210 of the semiconductor device testing apparatus in order to be placed close to the transistor 117 to be tested. The sample connection circuit 203 is connected to a connector 208 arranged on the side surface of the housing 210. The wiring connected to the connection pin 206 of the connector 208 is connected to the device control circuit board 209 in the B room.

The housing 210 is not limited to a box-like shape, and may be, for example, a room. This is an image in which the power supply circuit 121 is placed in a room. The partition walls 214, 215, and 217 may be walls of a room.

As shown in FIG. 15, the semiconductor element 117 (transistor, etc.) to be tested is placed in the C1 room. The transistor 117 and the like are arranged and fixed in close contact with the heating and cooling plate 134. If necessary, as shown in FIG . 1A , the transistor 117 and the like are sandwiched and fixed between the heating and cooling plates 134a and 134b. As described above, in the present invention, the casing 210 is divided into a plurality of areas such as the C1 room. The C1 chamber is configured so that dry air (dry gas, gas with a low dew point temperature) is injected. Air pressure is applied to the C1 chamber, and the air injected into the C1 chamber is discharged through the opening 216 and the like.

As shown in FIGS. 15 and 17, the connection structure 218 is inserted from the opening 216 of the partition wall 217 from the C2 chamber. By inserting the connection structure 218, the element terminal 226 of the transistor 117 and the connection structure 218 are electrically connected, and a constant current (test current) Id can be applied to the transistor 117. When the connection structure 218 is inserted through the opening 216, the element terminal 226 can be easily held between the connection receiving part 225 and the connection holding part 233 because the C part is cut as shown in FIG. .

The partition wall 217 functions as an electrostatic shield and a support for the connection structure 218. It goes without saying that the partition wall 217 can be omitted if an electrostatic shield function component, fixing or holding stand of the connection structure 218 is arranged or configured separately.
Furthermore, it goes without saying that if there is no partition wall 217, the element terminal 226 of the transistor 117 may be positioned and fixed to the connection structure 218.
The connection structure 218 is made of copper or a copper alloy, and its surface is plated with silver or nickel.

The partition wall 217 functions as an electromagnetic shield, an electrostatic shield, and a support for the connection structure 218. It goes without saying that the partition wall 217 can be omitted if an electromagnetic shield function component, an electrostatic shield function component, or a fixing or holding stand for the connection structure 218 is arranged or configured separately.
The partition walls 214, 215, and 217 may be constructed or formed of a member having an electromagnetic shield or an electrostatic shield.
Furthermore, it goes without saying that if there is no partition wall 217, the element terminal 226 of the transistor 117 may be positioned and fixed to the connection structure 218.

The partition walls (partition wall 214, partition wall 215, partition wall 217) have the function of separating each chamber (C1 chamber, C2 chamber, A chamber, B chamber) and the function of preventing outside air from flowing in. In particular, dry air is allowed to flow into the C1 chamber since dew condensation may occur in the C1 chamber during tests at low temperatures. The dry air that has flowed into the C1 chamber is discharged from the opening 216 to other chambers. However, if the opening 216 is large, a large amount of dry air is required. Therefore, it is preferable that the opening 216 has a size that allows the fork plug 205 as a connecting member and the connecting structure 218 to be inserted.

A fixing screw 221 is attached to the other end of the connection structure 218, and the connection wiring 211 is connected to the connection structure 218. A fork plug 205 as a connection member is attached to the other end of the connection wiring 211.

The fixing screw 221 is not limited to a screw, and may be any screw that can electrically connect the connection wiring 211 to the connection structure 218. For example, it goes without saying that a configuration or structure in which the connection wiring 211 is inserted under pressure may be used. Further, it goes without saying that the fixing screw 221 may be contacted by pressing with a spring (not shown).

The sample connection circuit 203 is connected to a device control circuit board 209 by a connection pin 206 of a connector 208. The sample connection circuit 203 is individually arranged corresponding to each transistor 117 to be tested, and the sample connection circuit 203 is configured to be easily removable.
The connectors 208 and 213 are not limited to connectors, and may be any type as long as they can electrically connect or disconnect wiring.

FIG. 18 is an explanatory diagram of the connection structure 218 in the semiconductor device testing apparatus of the present invention. The heat pipe 223 is in close contact with the recess 234 on the surface of the connection structure 218 . A thermally conductive grease or a heat dissipating silicone oil compound may be applied between the surface of the connection structure 218 and the heat pipe.

A recess 234 is formed in the connection structure 218 of the present invention, and the heat pipe 223 is fitted into the recess 234 . The heat pipe fitting 231 of the connection structure 218 is made of a material having a linear expansion coefficient smaller than that of the heat pipe 223.

Connection structure 218 is heated during testing. Therefore, the heat pipe 223 and the heat pipe fitting 231 are heated. The heating causes the heat pipe 223 and the heat pipe fittings 231 to expand.

In the present invention, a material is used in which the coefficient of linear expansion of the heat pipe fittings 231 of the connection structure 218 is smaller than that of the heat pipe 223, or the coefficient of linear expansion of the heat pipe 223 of the connection structure 218 is A material having a coefficient of linear expansion larger than that of the heat pipe fitting 231 is used. The material of the heat pipe 223 expands greatly within the recess 234, and the heat pipe 223 is firmly fitted into the recess 234. The heat pipe 223 will not come off from the heat pipe fitting 231. The more the heat pipe 223 heats up, the more the heat pipe 223 expands, the more the heat pipe 223 comes into close contact with the heat pipe fitting 231, and the better the heat dissipation becomes.

Examples of materials for the heat pipe fittings 231 include copper (coefficient of linear expansion 16.8), brass (coefficient of linear expansion 19), iron (coefficient of linear expansion 12.1), and stainless steel (SUS304) (coefficient of linear expansion 17.3). be done. Examples of materials for the heat pipe 223 include materials having a higher coefficient of linear expansion than the heat pipe fitting 231, such as aluminum (coefficient of linear expansion 23), tin (coefficient of linear expansion 26.9), and lead (coefficient of linear expansion 29.1). Ru. Among these, it is preferable to use copper (coefficient of linear expansion: 16.8) as the material for the heat pipe fitting 231, and to use aluminum (coefficient of linear expansion: 23) as the material for the heat pipe 223. Alternatively, an alloy obtained by mixing aluminum with a second metal such as molybdenum may be used.

The rate at which the length changes in response to a rise in temperature is called the coefficient of linear expansion. Similarly, the rate at which the volume changes is called the volumetric expansion coefficient. When α is the coefficient of linear expansion and β is the coefficient of volumetric expansion, there is a relationship β≈3α. The coefficient of thermal expansion indicates the rate at which the length and volume of an object expand (thermal expansion) due to a rise in temperature, per temperature. Also called coefficient of thermal expansion.

Therefore, in the present invention, a material having a coefficient of linear expansion of the heat pipe fitting 231 of the connection structure 218 is smaller than that of the heat pipe 223 is used, or a material that has a linear expansion coefficient of the heat pipe 223 of the connection structure 218 It is preferable to use a material having a coefficient of linear expansion larger than that of the heat pipe fitting 231. It goes without saying that the coefficient of linear expansion may be replaced by the coefficient of thermal expansion or the coefficient of volumetric expansion.

The recess 234 is formed in the heat pipe fitting 231. The heat pipe 223 is arranged so as to fit into the recess 234. By arranging the heat pipe 223 in the recess, the risk of damage to the heat pipe 223 is reduced.

The heat pipe fitting 231 is made of a metal that is electrically conductive and has good thermal conductivity. Examples of metals include copper and silver. In addition, carbon or the like other than metal may also be used.

It is preferable to use thermally conductive grease containing boron nitride (boron). It is preferable to use a silicone oil compound for heat dissipation that is a mixture of silicone oil as a base oil and a powder with good thermal conductivity such as alumina.
The heat pipe 223 is a hermetically sealed container in which a small amount of liquid (working fluid) is vacuum-sealed and has a capillary structure (wick) on the inner wall.

When a part of the heat pipe is heated, the working fluid evaporates (absorbs latent heat of vaporization) in the heated part, and steam moves at high speed (sonic speed) to the cold part. Steam condenses in the low-temperature section (releasing latent heat of vaporization), and the condensed working fluid flows back to the heating section due to the wick's capillary action. By continuously repeating the above phase change without external force, heat is transferred instantaneously, so that the heat generated at the terminal portion of the semiconductor element can be transferred quickly and efficiently.

The heat pipe 223 is configured by arranging a plurality of containers (copper pipes). The interior of the container is under highly reduced pressure and contains a wick (capillary structure) and an appropriate amount of working fluid (pure water, etc.).
As the working fluid, in addition to pure water, methanol (methyl alcohol), acetone, sodium, mercury, fluorocarbon refrigerant, or ammonia may be used.
As the wick material, aluminum, copper, stainless steel, sintered alloy, wire mesh, foam metal, ceramic, etc. are used.

The connection structure 218 is not limited to metal. For example, it goes without saying that it may be made of a non-metallic material such as ceramic, graphite, or a composite material of graphite and copper or aluminum. In the case of a configuration in which a current is directly applied to the connection structure 218, the connection structure 218 is made of a metal material such as copper. The surface of the connection structure 218 is preferably plated with silver, nickel, or the like.
FIG. 18 is an explanatory diagram of the configuration of the connection structure 218. FIG. 18(a) is a diagram schematically illustrating the back surface, and FIG. 18(b) is a diagram schematically illustrating the side surface.

As shown in FIG. 18, the connection structure 218 mainly includes a heat pipe fitting 231, a connection receiving part 225, a connection pressure part 232, and a connection holding part 233. An element terminal 226 of a semiconductor element is inserted between the connection receiving part 225 and the connection holding part 233.

A spring 236 is inserted or arranged in the spring hole 239 of the connection receiving part 225 and the connection pressure part 232. The positioning screw 237 is inserted or arranged in the positioning screw hole 240 in the center of the connection receiving part 225, and the connection receiving part 225 and the connection pressure part 232 are positioned.

The spring 236 is a pressure generating means, a sliding means, or a positioning means. A coil spring is exemplified. Other examples include leaf springs, spiral springs, tension bars, and disc springs. In this specification, for ease of explanation, a coil spring is used as an example of the spring. However, it is not limited to coil springs.
The spring 236 is preferably formed or constructed from a metal material with good electrical conductivity, but may also be formed from a heat-resistant rubber, plastic, or ceramic material.

A coil spring 236 is arranged between the connection receiving part 225 and the connection pressure part 232. The connecting pressure section 232 is connected with one or more fixing screws 224b. By tightening or attaching the fixing screw 224b, pressure (pressure) is applied between the connection receiving part 225 and the connection holding part 233. The element terminal 226 is sandwiched between the connection receiving part 225 and the connection holding part 233, and the element terminal 226 is held between the connection receiving part 225 and the connection holding part 233 with a predetermined pressure (predetermined pressing force) due to the pressure of the spring 236.

In FIG. 18, the heat pipe fitting 231 and the connection holding part 233 are shown to be separate members, and are connected to each other by a fixing screw 224a. It goes without saying that the heat pipe fitting 231 and the connection holding part 233 may be integrated into one member.
FIG. 1 is a configuration and explanatory diagram of a connection portion with an element terminal 226 such as a transistor 117 in an electric element testing apparatus of the present invention.

In FIG. 1A, the connection holding part 233 is fixed to the heat pipe fitting 231 with a fixing screw 224a. The connection pressure part 232 is fixed to the connection holding part 233 with a fixing screw 224b. The element terminals 226 of the semiconductor element are fixed by tightening or arranging the fixing screws 224b. The connection wiring 211 is fixed to the left end of the heat pipe fitting 231 with a fixing screw 221.

The pressure (pressure) can be easily adjusted by changing the spring 236. Moreover, the pressure (pressure) can be adjusted or set by the degree of tightening of the fixing screw 224b. The heat pipe fitting 231 and the connection holding part 233 are fixed with one or more fixing screws 224a.

As shown by C in FIGS. 1, 4, etc., the portion (edge) into which the element terminal 226 is inserted is cut at 45°. By cutting the edge, the connection structure 218 can be easily inserted into the element terminal 226 when the connection structure 218 is inserted through the opening 216 of the partition wall 217 and connected to the element terminal 226. The edge cut may have other shapes such as an arcuate shape.

A connection receiving part 225 is arranged between the connection pressure part 232 and the connection holding part 233. As the constituent material or at least the surface material of the connection receiving portion 225, platinum, gold, silver, tungsten, copper, nickel, or an alloy of a combination thereof is used. It is also preferable to use silver-oxide contact materials (Ag+ZnO, Ag+SnO ₂ , Ag+SnO ₂ In ₂ O ₃ , Ag+, Ag+SnO ₂ Sn ₂ Bi ₂ O ₇ ).

Similarly, platinum, gold, silver, tungsten, copper, nickel, or a combination thereof is used as a material for the surface of the connection holding portion 233 in contact with the element terminal 226. It is also preferable to use silver-oxide contact materials (Ag+ZnO, Ag+SnO ₂ , Ag+SnO ₂ In ₂ O ₃ , Ag+, Ag+SnO ₂ Sn ₂ Bi ₂ O ₇ ).

The connection holding part 233 is fixed to the heat pipe fitting 231 with a fixing screw 224a. The connection pressure part 232 is fixed to the connection holding part 233 with a fixing screw 224b. The element terminals 226 of the semiconductor element are fixed by tightening or arranging the fixing screws 224b. The connection wiring 211 is fixed to the left end of the heat pipe fitting 231 with a fixing screw 221.

The connection holding part 233 and the heat pipe fitting 231 may be integrated into one component without using the fixing screw 224a. By configuring them as one piece, the heat generated by the element terminal 226 is efficiently transferred from the connection holding part 233 to the heat pipe fitting 231, and the transferred heat is radiated by the heat pipe 223.

As shown in FIG. 1(b), by integrating the heat pipe fitting 231 and the connection holding part 233, the heat of the connection holding part 233 is easily transferred to the heat pipe fitting 231, and the heat at the element terminal 226 is easily transferred to the heat pipe fitting 231. Heat dissipation is improved. Further, as shown in FIGS. 1(b), 19(a), and 20, by arranging the heat pipe 223 also near the element terminal 226, the heat generated by the element terminal 226 can be efficiently dissipated.
It goes without saying that the above matters can also be applied to other embodiments of the present invention such as FIG. 1(a), FIG. 4, FIG. 6, FIG. 7, FIG. 10, FIG. 11, and FIG.

FIG. 3 is a plan view of members constituting a connecting portion that electrically and thermally connects to the element terminal 226. In FIGS. 7, 2, etc., there is one fixing screw 224b that fixes the connection holding part 233 and the connection pressure part 232, but in FIGS. 3, 4, 5, etc., there are two fixing screws 224b. . Also, in FIGS. 7, 2, etc., there is one fixing screw 224a that fixes the connection holding part 233 and the heat pipe fitting 231, but in FIGS. 3, 4, 5, etc., there are two fixing screws 224a. It is said that

As described above, the number of fixing screws 224 to be used is appropriately selected and designed depending on the fixing state. Note that although the fixing screw 224 is used in this specification, the connection is not limited to the fixing screw, and connection may be made using other materials. Examples include welding by electricity or arc discharge, spot welding, resistance welding, laser welding, TIG welding, ultrasonic welding, electronic beam welding, soldering, and crimping.
3, 4, and 5 are explanatory diagrams illustrating a combined state of the connection holding part 233, the connection receiving part 225, and the connection pressure part 232.

FIG. 3A is a plan view of the connection holding part 233. In FIG. 3A, the fixing screw 224b is inserted into the screw hole 238b1 and the screw hole 238b2, and the connection holding part 233 and the connection pressure part 232 are fixed. Further, the fixing screw 224a is inserted into the screw hole 238a1 and the screw hole 238a2, and the connection holding part 233 and the heat pipe fitting 231 are fixed.

In FIG. 3A, the fixing screw 224b is inserted into the screw hole 238b1 and the screw hole 238b2, and the connection holding part 233 and the connection pressure part 232 are fixed. Moreover, the fixing screw 224a is inserted into the screw hole 238a1 and the screw hole 238a2, and the connection holding part 233 and the heat pipe fitting 231 are fixed.

FIG. 3(b) is a plan view of the connection receiving portion 225. In FIG. 3(b), spring holes 239 are formed at each of the four corners. A positioning screw hole 240 is formed in the center. The distance between the connection receiving part 225 and the connection pressure part 232 is adjusted or set by the position fixing screw 237 in the positioning screw hole 240. By adjusting the distance between the connection receiving portion 225 and the connection pressure portion 232, the pressure (pressure) of the spring 236 is set to a predetermined value.

Spring holes 239 are formed at each of the four corners, and a spring 236 is held between the spring holes 239 of the connection receiving part 225 and the spring holes 239 of the connection pressure part 232. Since the springs 236 are held at the four corners, the pressure can be adjusted equally at the four corners of the connection receiving portion 225 by the positioning screw holes 240.

Moreover, the positioning screw hole 240 fixes the position of the connection pressure part 232 and the connection receiving part 225. Therefore, the element terminal 226 held between the connection receiving part 225 and the connection holding part 233 does not move.

FIG. 3(c) is a plan view of the connection pressure section 232. In FIG. 3(c), spring holes 239 are formed at each of the four corners. A positioning screw hole 240 is formed in the center. The distance between the connection receiving part 225 and the connection pressure part 232 is adjusted or set by the position fixing screw 237 in the positioning screw hole 240. By adjusting the distance between the connection receiving portion 225 and the connection pressure portion 232, the pressure of the spring 236 is set to a predetermined value.

Spring holes 239 are formed at each of the four corners, and a spring 236 is held between the spring holes 239 of the connection receiving part 225 and the spring holes 239 of the connection pressure part 232. The spring 236 is fitted and inserted into the spring hole 239. Since the springs 236 are held at the four corners, the pressure can be adjusted equally at the four corners of the connection receiving portion 225 by the positioning screw holes 240. Further, the positioning screw hole 240 fixes the connection pressure part 232 and the connection receiving part 225 in position.

FIG. 5 is an explanatory diagram illustrating a combined state of the connection holding part 233, the connection receiving part 225, and the connection pressure part 232. FIG. 4 is a perspective view of a combined state of the connection holding part 233, the connection receiving part 225, and the connection pressure part 232.

The connection holding portion 233 connects and fixes the heat pipe 223 and the heat pipe fitting 231 using screws 224a (not shown) inserted into the screw holes 238a1 and 238a2. The heat pipe 223 and the heat pipe fitting 231 are closely connected and fixed so as to have good thermal conductivity and electrical conductivity. Further, the connection holding part 233 is connected and fixed to the connection pressure part 232 by screws 224b (not shown) inserted into the screw holes 238b1 and 238b2.

FIG. 4 shows a state in which the connection holding part 233, the connection receiving part 225, and the connection pressure part 232 are combined. However, the screw holes 238 and position fixing screws 237 are omitted from illustration. The configuration of FIG. 4 is connected to and fixed to the heat pipe fitting 231.

The fixing screw 224b is inserted into the screw hole 238b1 and the screw hole 238b2, and the connection holding part 233 and the connection pressure part 232 are fixed. Moreover, the fixing screw 224a is inserted into the screw hole 238a1 and the screw hole 238a2, and the connection holding part 233 and the heat pipe fitting 231 are fixed.

The connection receiving part 225 has convex parts 251 formed at both ends, and the connection pressure part 232 has groove parts 252 formed at both ends. The convex portion 251 of the connection receiving portion 225 is fitted into the groove portion 252 of the connection pressure portion 232. The convex portion 251 of the connection receiving portion 225 and the groove portion 252 of the connection pressure portion 232 are configured to be in electrical contact with each other.

As illustrated in FIGS. 4 and 5, the connection holding portion 233 connects and fixes the heat pipe 223 and the heat pipe fitting 231 using screws 224a inserted into the screw holes 238a1 and 238a2. The heat pipe 223 and the heat pipe fitting 231 are closely connected and fixed so as to have good thermal conductivity and electrical conductivity. Further, the connection holding part 233 is connected and fixed to the connection pressure part 232 by screws 224b inserted into the screw holes 238b1 and 238b2.

The connection receiving part 225 has convex parts 251 formed at both ends, and the connection pressure part 232 has groove parts 252 formed at both ends. The convex portion 251 of the connection receiving portion 225 is fitted into the groove portion 252 of the connection pressure portion 232. The convex portion 251 of the connection receiving portion 225 and the groove portion 252 of the connection pressure portion 232 are configured to be in electrical contact with each other.

In order to improve the contact between the element terminal 226 and the connection receiving part 225, as shown in FIGS. 2(b) and 2(c), irregularities such as triangular shapes are formed on the surface of the connection receiving part 225. is preferred. The convex portion makes strong contact with the element terminal 226, resulting in a good electrical connection.

As shown in FIG. 2A, the element terminal 226 is held between the connection receiving part 225 and the connection holding part 233. As shown in FIG. 2B, triangular irregularities are formed on the surface of the connection receiving portion 225 in parallel to the direction in which the element terminal 226 is inserted. Pressure is more firmly applied between the triangular peak shown in FIG. 2(c) and the element terminal 226, and good contact can be achieved. xAlso, the shape is not limited to a triangular shape, but may be an embossed shape or a protrusion shape.

It goes without saying that the processing shown in FIG. 2(c) may be performed on the surface of the connection holding portion 233 that is in contact with the element terminal 226. Furthermore, it goes without saying that the shape is not limited to a triangular shape, but may be other shapes such as an arc shape, a projection shape, or an embossed shape.
The configuration shown in FIG. 1 is such that the element terminal 226 is sandwiched between the plane of the connection pressure section 232 and the plane of the connection holding section 233.

FIG. 6 shows a configuration in which the element terminal 226 is held between the pressing tool mounting plate 313 and the connection holding part 233. A pressing tool 311a and a pressing tool 311b are attached to the pressing tool mounting plate 313. The pressing tool 311 is, for example, a plate spring made of metal. Note that the pressing tool 311 may be formed of a non-conductive material such as a silicone resin material. A pressing tool 311 is fitted into a pressing tool mounting plate 313.
As shown in FIG. 6, the lower surface of the element terminal 226 is in surface contact with the connection holding part 233, and the upper surface of the element terminal 226 is held between the pressing tools 311.

The element terminal 226 is held between the planes of the pressing tool 311 and the connection holding part 233. By pressing with the pressing tool 311, the element terminal 226 and the connection holding part 233 are electrically connected.

In the embodiment of FIG. 1A, the spring (pressure fitting) 236 is inserted into the spring hole 239 of the connection receiving part 225. When the spring (pressure fitting) 236, connection receiving part 225, and connection pressure part 232 are made of conductive material, the element terminal 226 -> connection receiving part 225 -> spring (pressure fitting) 236 -> connection pressure part 232 Electricity may flow. In this case, if the resistance value of the spring (pressure fitting) 236 is large, current may flow through the spring (pressure fitting) 236, causing the spring or the like to generate heat and burn out.

By configuring any one of the connection receiving part 225, the spring (pressure fitting) 236, and the connection pressure part 232 with a non-conductive material, the above-mentioned current path is not generated, and the occurrence of burnout of the spring or the like is also eliminated. A configuration in which heat is transferred to the connection holding portion 233 and then to the heat pipe 223 is preferable. As shown in FIG. 1(b) etc., the heat pipe fitting 231 and the connection holding part 233 are integrated, and the heat generated by the element terminal 226 is transferred to the heat pipe fitting 231 and then to the heat pipe 223. A configuration in which this is the case is preferable.

In the embodiment of FIG. 6, when the pressing tool 311, the spring (pressure fitting) 236, the connection receiving part 225, and the connection pressure part 232 are made of conductive material, the element terminal 226 -> the pressing tool 311 -> the connection receiving part 225 -> Spring (pressure fitting) 236 -> Electricity may flow to the connection pressure part 232. In this case, if the resistance value of the spring (pressure fitting) 236 is large, current may flow through the spring (pressure fitting) 236, causing the spring or the like to generate heat and burn out.

By configuring any one of the pressing tool 311, the connection receiving part 225, the spring (pressure fitting) 236, and the connection pressure part 232 with a non-conductive material, the occurrence of the above-mentioned current path is eliminated, and the occurrence of burnout of the spring etc. is also eliminated. . As shown in FIG. 1(b) etc., the heat pipe fitting 231 and the connection holding part 233 are integrated, and the heat generated by the element terminal 226 is transferred to the heat pipe fitting 231 and then to the heat pipe 223. A configuration in which this is the case is preferable.

FIG. 7 is an explanatory diagram of a state in which an element terminal 226 of a semiconductor element is connected to a connection structure 218 in an electric element testing apparatus according to another embodiment of the present invention. An element terminal 226 is held between the connection receiving part 225 and the connection holding part 233. The connection pressure part 232 is fixed to the connection holding part 233 by a fixing screw 224b.

In the embodiment of the invention of FIG. 7, screw holes 239 are formed in the insulating plate 312. The pressing tool 311 contacts the element terminal 226, and the spring 236 presses the pressing tool mounting plate 313. An insulating plate 312 is arranged above the pressing tool mounting plate 313 to insulate between the pressing tool mounting plate 313 and the spring 236. A spring hole 239 is formed in the insulating plate 312, and a spring 236 is inserted into the spring hole 239. The other configurations are the same as those in FIG. 6, so their explanation will be omitted.

The insulating plate 312 may be an insulating film, an insulating film, an insulating gas such as air, or the like. Alternatively, it may be a combination of a plurality of insulators. Further, an insulating material or an insulating film may be formed on the surface of the connection receiving portion 225 by processing hexavalent chromium, alumite, or the like.

In FIG. 7, for ease of understanding, the connection pressure section 232 and the connection holding section 233 are illustrated as having a space, but in reality, the connection pressure section 232 and the connection holding section 233 are electrically connected. Connected.

FIG. 7 is a diagram showing a state in which the element terminal 226 is held between the connection receiving part 225 and the connection pressure part 232. The element terminal 226 is press-fitted between the connection receiving part 225 and the connection holding part 233 to be electrically connected.

The connection receiving portion 225 is configured to be able to slide up and down by springs 236 placed at four corners. The connection receiving portion 225 is positioned by a screw pin (position fixing pin) 237 inserted into the positioning screw hole 240. Therefore, the connection receiving part 225 can be slid up and down without being displaced.

An element terminal 226 of a semiconductor element to be tested is inserted between the connection holding part 233 and the connection receiving part 225. The C portions of the connection receiving portion 225 and the connection holding portion 233 have cut edges. Therefore, the element terminals 226 of the semiconductor element can be easily inserted.
Therefore, by inserting the connection structure 218 from the C2 chamber into the C1 chamber, it is possible to easily electrically connect the element terminal 226 of the semiconductor element 117.

FIG. 8 is an explanatory diagram and a configuration diagram of the press mounting plate 313 of FIG. 6. 8(a) is a side view of the press attachment plate 313, and FIG. 8(b) is a bottom view of the press attachment plate 313 viewed from the back side.

As shown in FIG. 8(b), a plurality of pressing tools 311a and a plurality of pressing tools 311b are arranged in a matrix on the back side of the pressing mounting plate 313. Further, as shown in FIG. 8(a), a pressing tool 311 is fitted into a pressing mounting plate 313.

A positioning screw hole 240 is formed in the press mounting plate 313, and a positioning fixing screw 237 is inserted into the positioning screw hole 240. Further, a spring hole 239 is formed in the press mounting plate 313, and a spring 236 is inserted into the spring hole 239. In the embodiment of FIG. A good pressure is applied to maintain a good electrical connection.

In the embodiment of FIG. 6, a spring (pressure fitting) 236 is inserted into a spring hole 239 of the connection receiving part 225. When the spring (pressure fitting) 236, connection receiving part 225, and connection pressure part 232 are made of conductive material, the element terminal 226 -> connection receiving part 225 -> spring (pressure fitting) 236 -> connection pressure part 232 Electricity may flow. In this case, if the resistance value of the spring (pressure fitting) 236 is large, current may flow through the spring (pressure fitting) 236, causing the spring to generate heat and burn out.

If the pressing tool 311 is made of a non-conductive material and configured so that no current flows through the pressing tool mounting plate 313, the above-mentioned current path will not occur and the spring (pressure fitting) 236 will not burn out. .

FIG. 7 is an explanatory diagram and a configuration diagram of a connection structure 218 in another embodiment of the present invention. In the embodiment of the invention of FIG. 7, screw holes 239 are formed in the insulating plate 312. The pressing tool 311 contacts the element terminal 226, and the spring 236 presses the pressing tool mounting plate 313. An insulating plate 312 is arranged above the pressing tool mounting plate 313 to insulate between the pressing tool mounting plate 313 and the spring 236. A spring hole 239 is formed in the insulating plate 312, and a spring 236 is inserted into the spring hole 239.

As shown in FIG. 7, the pressing tool 311 comes into contact with the element terminal 226, and the spring 236 presses the pressing tool mounting plate 313. An insulating plate 312 is arranged above the pressing tool mounting plate 313 to insulate between the pressing tool mounting plate 313 and the spring 236. A spring hole 239 is formed in the insulating plate 312, and a spring 236 is inserted into the spring hole 239. The other configurations are the same as those in FIG. 6, so their explanation will be omitted.

FIG. 9 is an explanatory diagram of the pressing tool mounting plate 313 and the insulating plate 312 portion of the connection structure 218 of FIG. 7. FIG. 9(a) is a side view of the pressing tool attachment plate 313. As shown in FIG. FIG. 9(b) is a side view of the pressing tool attachment plate 313 section seen from the A side of FIG. 9(a).

A pressing tool 311a and a pressing tool 311b are arranged and inserted into the pressing tool mounting plate 313. In the embodiment shown in FIG. 9, the insulating plate 312 and the convex portion 251 are made of an insulating material, and the screw holes 239 are formed in the insulating plate 312. Therefore, since the screw hole 239 is insulated, no current path is generated in the connection pressure section 232.

Since the insulating plate 312 is made of an insulating material, no current flows through the spring (pressure fitting) 236 even if the pressing tool mounting plate 313 is a conductive material such as metal. Therefore, a current path from element terminal 226 -> connection receiving part 225 -> spring (pressure fitting) 236 -> connection pressure part 232 is not generated.

Note that the insulating plate 312 may be an insulating film, an insulating film, an insulating gas such as air, or the like. Further, the pressing tool attachment plate 313 may be made of a non-conductive material. Further, an insulating material or an insulating film may be formed using hexavalent chromium, alumite processing, or the like.

As illustrated in FIG. 1(b), by configuring the heat pipe fitting 231 and the connection holding part 233 as one piece, it is possible to apply current or the like from the heat pipe fitting 231 to the element terminal 226 without voltage drop. No current flows to the connection receiving portion 225 side. Further, as shown in FIG. 1B, by arranging the heat pipe 223 close to the element terminal 226, the heat generated at the element terminal 226 and the like is efficiently transferred through the heat pipe 223.

Note that, as shown in FIGS. 1, 4, etc., it is preferable to arrange a thermocouple 316 and monitor the temperature of the element terminal 226 and the electric element 117 to perform test control. The above matters also apply to other embodiments of the present invention. As shown in FIG. 26, it is preferable to also monitor the temperature of the switch circuit board 201 and the like.

The embodiment shown in FIG. 7 has a configuration in which insulation is provided by an insulating plate 312. The insulating effect in the present invention is not limited to the configuration using the insulating plate 312 as shown in FIG. For example, the configuration illustrated in FIG. 10 is exemplified.

FIG. 10 shows a configuration in which an insulating part 315 made of a resin material or the like is arranged around the screw hole 238b of the connection pressure part 232. FIG. 12 is a configuration diagram of the connection pressure section 232 of FIG. 10 viewed from the back side. As shown in FIG. 12, the periphery of the screw hole 238b surrounds the insulating portion 315, so that the screw can be insulated. Note that the fixing screw 224b may be made of an insulating material.

Since the periphery of the screw hole 238b is insulated by the insulating portion 315, no current flows through the fixing screw 224b. Therefore, a current path from element terminal 226 -> connection receiving part 225 -> spring (pressure fitting) 236 -> connection pressure part 232 is not generated, and the spring (pressure fitting) 236 is not burnt out.

As described above, the present invention is configured such that the insulating plate 312 is disposed on the side of the spring 236 that applies pressure so that the current does not flow to the side of the pressing tool mounting plate 313 and the connection receiving part 225.

When the current flows, it flows through the pressing parts such as the spring 236 and the fixing screw 224b, and the spring 236 and the fixing screw 224b are burnt out. A current is supplied to the element terminal 226 through the connection holding part 233 side, which has fewer electrically high resistance parts such as the spring 236.

6, FIG. 7, and FIG. 10 are examples of the connection structure 218 having the pressing tool 311. The present invention is not limited to this, and may have the configuration shown in FIG. 11, for example.

FIG. 11 shows a configuration in which an element terminal 226 is held between a connection receiving part 225 and a connection holding part 233. By roughening the surface of the connection receiving portion 225, pressure can be uniformly applied to the element terminal 226. By forming the connection receiving portion 225 with an insulating material, it is possible to prevent a current path from occurring in the connection pressure portion 232.

It goes without saying that preventing a current path from occurring on the connection pressure section 232 side can also be achieved by configuring the fixing screw 224b and the connection pressure section 232 with an insulator.

As shown in FIG. 13, the transistor 117 is fixed to a heating/cooling plate 134a and held between heating/cooling plates 134b. Transistor 117 is suitably maintained at the test temperature by heating and cooling plate 134. As shown in FIG. 18, a heat pipe 223 is installed within the recess 234.

A test constant current Id is applied from the connection structure 218 to the element terminal 226. The constant current Id is as large as several hundred amperes (A). Contact resistance may occur between the connection receiving portion 225 and the element terminal 226. If there is contact resistance, the connection receiving portion 225 generates heat when a large current flows through the element terminal 226.

The heat generated is conducted to the transistor 117 under test, causing the transistor 117 to overheat. Overheating may cause the transistor 117 to deteriorate or the element terminal 226 to burn out. Therefore, it is necessary to quickly dissipate the heat generated in the connection receiving portion 225.

The connection structure 218 of the present invention has a heat pipe 223. The heat generated in the connection receiving portion 225 is transferred through the heat pipe 223. Therefore, the heat of the connection receiving part 225 is quickly removed from the connection receiving part 225.

FIG. 9(a) is a side view of the pressing tool attachment plate 313. As shown in FIG. A pressing tool 311a and a pressing tool 311b are arranged and inserted into the pressing tool mounting plate 313. FIG. 9(b) is a view seen from direction A in FIG. 9(a).

Since the insulating plate 312 is made of an insulating material, no current flows through the spring (pressure fitting) 236 even if the pressing tool mounting plate 313 is a conductive material such as metal. Therefore, a current path from element terminal 226 -> connection receiving part 225 -> spring (pressure fitting) 236 -> connection pressure part 232 is not generated.

The embodiment shown in FIG. 7 has a configuration in which insulation is provided by an insulating plate 312. The insulating effect in the present invention is not limited to the configuration using the insulating plate 312 as shown in FIG. For example, the configuration illustrated in FIG. 12 is exemplified.

FIG. 12 shows a configuration in which an insulating part 315 made of a resin material or the like is arranged around the screw hole 238b of the connection pressure part 232. Since the periphery of the screw hole 238b is insulated by the insulating portion 315, no current flows through the fixing screw 224b. Therefore, a current path from element terminal 226 -> connection receiving part 225 -> spring (pressure fitting) 236 -> connection pressure part 232 is not generated, and the spring (pressure fitting) 236 is not burnt out.

As described above, the present invention is configured such that the insulating plate 312 is disposed on the side of the spring 236 that applies pressure so that the current does not flow to the side of the pressing tool mounting plate 313 and the connection receiving part 225.

When the current flows, it flows through the pressing parts such as the spring 236 and the fixing screw 224b, and the spring 236 and the fixing screw 224b are burnt out. A current is supplied to the element terminal 226 through the connection holding part 233 side, which has fewer electrically high resistance parts such as the spring 236.

The present invention has a structure in which the connection receiving part 225 slides in the vertical direction and the element terminal 226 is closely held between the connection holding part 233 and the connection receiving part 225, so that the occurrence of contact resistance is extremely small. . Further, even if the semiconductor element 117 moves due to vibration or the like during the test, since the element terminals 226 are held, there is no positional movement and the electrical connection is maintained well.

38 and 39 are explanatory diagrams of the semiconductor element 117 to be tested as an example. FIG. 38 illustrates a transistor as the semiconductor element 117. The transistor 117 has a P terminal (collector terminal of the transistor 117) to which a large current is applied and an N terminal (emitter terminal of the transistor 117) to which a large current is applied. A diode Di is formed or added between the emitter terminal and the collector terminal. Apply test current Id to the P and N terminals.

The transistor 117 has a collector terminal c, a gate terminal g, and an emitter terminal e. A signal Vgs for turning on and off the transistor 117 is applied to the gate terminal g. A constant current Ic is passed from a constant current circuit 118 to a diode Di between the emitter terminal e and the collector terminal c.

As shown in FIGS. 15 and 17, a partition wall 217 is arranged between the C1 chamber and the C2 chamber. An opening 216 is formed in the partition wall 217 . The connection structure 218a1 is inserted into the opening 216a1, and the connection structure 218b1 is inserted into the opening 216b1. The connection structure 218a2 is inserted into the opening 216a2, and the connection structure 218b2 is inserted into the opening 216b2. A connecting structure 218an is inserted into the opening 216an, and a connecting structure 218bn is inserted into the opening 216bn.

For example, in the semiconductor device testing apparatus of the present invention shown in FIG. 29, the P terminal of the transistor 117Q1 to be tested is sandwiched between the connection receiving portion 225 and the connection holding portion 233 of the connection structure 218a1 and electrically connected. Further, the N terminal of the transistor 117Q1 to be tested is sandwiched between the connection receiving portion 225 and the connection holding portion 233 of the connection structure 218b1 and electrically connected.

Similarly, the P terminal of the transistor 117Q2 to be tested is sandwiched between the connection receiving portion 225 and the connection holding portion 233 of the connection structure 218a2 and electrically connected. Further, the N terminal of the transistor 117Q2 to be tested is sandwiched between the connection receiving portion 225 and the connection holding portion 233 of the connection structure 218b2 and electrically connected.

Similarly, the P terminal of the transistor 117Qn to be tested is sandwiched between the connection receiving portion 225 and the connection holding portion 233 of the connection structure 218an and electrically connected. Further, the N terminal of the transistor 117Qn to be tested is sandwiched between the connection receiving portion 225 and the connection holding portion 233 of the connection structure 218bn and is electrically connected.

An electrostatic shielding plate or an electrostatic shielding network is arranged on the partition wall 217, and noise from the power supply device 132 and the drive circuit system of the B room is shielded, and the noise is not propagated to the C1 room. Furthermore, noise generated by turning on and off the transistor 117 is not propagated to the drive circuit system in the B room.

FIG. 22 is an explanatory diagram illustrating the connection state between the transistor 117 and the connection structure 218. The transistor 117 is fixed in close contact with the heating/cooling plate 134a. Fixation is achieved by springs (not shown). For adhesion, thermally conductive grease or heat dissipating silicone oil compound may be applied. If necessary, as shown in FIG . 1A , a heating and cooling plate 134b is also arranged above the transistor 117, so that the transistor 117 can be set to a predetermined temperature condition.

A connector 202 is connected to the terminals (emitter terminal e, gate terminal g, collector terminal c) of the transistor 117. A signal wiring 222 is drawn out to the connector 202. A control signal Vgs applied to the gate terminal g of the transistor 117 and a constant current Ic from the constant current circuit 118 are applied to the signal wiring 222 .

As shown in FIG. 22 etc., the connection structure 218a is inserted into the opening 216a of the partition wall 217 from the C2 chamber side. The connecting structure 218b is similarly inserted into the opening 216b of the partition wall 217 from the C2 chamber side. When the connection structure 218 is inserted, the element terminal 226 is sandwiched between the connection receiving part 225 and the connection holding part 233. In this state, the element terminal 226 of the transistor 117 and the connection structure 218 are electrically connected by tightening the fixing screw 224b.

Since the transistor 117 to be tested needs to be fixed in close contact with the heating/cooling plate 134, it is difficult to remove it easily. To attach the transistors 117, first, a plurality of transistors 117 to be tested are fixed to the heating/cooling plate 134. Next, the transistor 117 to be tested first is selected and the connection structure 218 is attached to the element terminal 226.

The transistor 117 to be selected is electrically connected to the element terminal 226 by inserting the connection structure 218 from the C2 chamber side into the opening 216 where the transistor 117 to be selected is located.

Electrical connection with the transistor 117 is easy because it is only necessary to select a position to insert the connection structure 218. Furthermore, by changing the signal applied to the connection wiring 211 connected to the connection structure 218, the test conditions and test contents of the transistor 117 can be easily changed.

The element terminal 226 is held between the connection receiving portion 225 and the connection holding portion 233 while applying pressure. A connection wiring 211 is connected to one end of the connection structure 218, and a constant current Id is applied from the connection wiring 211 to the transistor 117. A heat pipe 223 is arranged on the back side of the connection structure 218. By arranging the heat pipe 223 on the back side of the connection structure 218, occurrence of mechanical damage is reduced. Further, as shown in FIG. 22, cooling by the cooling fan 227 is also facilitated.

A current of several hundred amperes (A) flows through the element terminal 226. Even if there is a slight resistance in the connection receiving portion 225 or the like, a large amount of heat is generated due to the current of several hundred amperes (A), overheating the element terminal 226 portion. If the transistor 117 is overheated, the transistor 117 will also be overheated, and the overheating will cause the transistor 117 to deteriorate or be destroyed.

In the present invention, heat generated in the connection receiving part 225, the connection holding part 233, etc. is transferred to the connection wiring 211 side of the connection structure 218 by the heat pipe 223. Therefore, the connection receiving part 225, the connection holding part 233, etc. are not overheated. A cooling fan 227 is disposed below the connection structure 218 or is directly cooled with water to radiate heat from the heat pipe 223 .
FIG. 23 is an explanatory diagram illustrating a method of connecting the semiconductor element 117 and the connection structure 218 in the semiconductor testing apparatus of the present invention.

A partition wall 217 is provided between the C1 chamber and the C2 chamber. As shown in FIG. 17, openings 216 are formed in the partition wall 217 in correspondence with the positions of the transistors 117 and the like to be tested. The connection structure 218 is horizontally or stably positioned and fixed by the opening 216 of the partition wall 217 and the fixing base (not shown) of the connection structure 218.

As shown in FIG. 23(a), the transistor 117 to be tested is positioned and fixed in close contact with the heating/cooling plate 134a. Thermal conductive grease and heat dissipation silicone oil compound are applied between the transistor 117 and the heating/cooling plate 134a.

A detachable connector 202 is connected to the terminals (emitter terminal e, gate terminal g, collector terminal c) of the transistor 117. A signal wiring 222 is connected to the connector 202, and the signal wiring 222 is connected to a sample connection circuit 203.

The signal wiring 222 between the sample connection circuit 203 and the connector 202 is formed to be as short as possible. If the signal wiring 222 is long, noise will be superimposed on the signal wiring 222, causing the transistor 117 to malfunction. For example, if noise is superimposed on the gate terminal g of the transistor 117, the transistor 117 may turn on and be destroyed. The signal wiring 222 may be a twisted wiring or a shielded wiring such as a coaxial cable.

As shown in FIG. 15, the connector 208 is provided on the side surface of the casing 210, and the connector 208 and the device control circuit board 209 arranged in the B room are connected by a signal wiring 235. Control signals or output signals of the gate driver circuit 113, gate signal control circuit 112, temperature measurement circuit 115, variable resistance circuit 125, and operational amplifier circuit 116 are input and output from the device control circuit board 209.

As shown in FIG. 23(b), a connecting structure 218a is inserted into the opening 216a. As shown in FIGS. 4 and 5, the edge portions indicated by C of the connection receiving portion 225 and the connection holding portion 233 are cut or processed into an arc shape, so that even if the position of the element terminal 226 changes slightly, , can be inserted well into the connection receiving part 225 and the connection holding part 233, and the element terminal 226 can be held between them.

When the connection structure 218a is inserted into the opening 216a, the element terminal 226a of the transistor 117 is held between the connection receiving part 225 and the connection holding part 233 at the tip of the connection structure 218a. After the connection structure 218a and the element terminal 226a are connected, by tightening the fixing screw 224b1, a good electrical connection between the connection receiving part 225 and the element terminal 226 can be realized.

Similarly, connection structure 218b is inserted into opening 216b. When the connection structure 218b is inserted into the opening 216b, the element terminal 226b of the transistor 117 is held between the connection receiving part 225 and the connection holding part 233 at the tip of the connection structure 218b. After the connection structure 218b and the element terminal 226b are connected, by tightening the fixing screw 224b2, a good electrical connection between the connection receiving part 225 and the element terminal 226 can be realized.

A cooling fan 227 for removing heat from the heat pipe 223 is arranged on the back surface of the connection structure 218 . The rotation speed of the cooling fan 227 is controlled depending on the overheating status of the element terminal 226 and the heat pipe 223.

In the embodiment shown in FIG. 18, the heat pipe 223 is attached to the recess 234 of the heat pipe fitting 231 of the connection structure 218. However, the present invention is not limited to this.

For example, the connection structure 218 may be configured as illustrated in FIG. In FIG. 19, FIG. 19(a) is a schematic illustration of the back surface (bottom surface) of the connection structure 218, and FIG. 19(b) is a schematic illustration of the surface (top surface) of the connection structure 218. It is something.

In FIG. 19, a heat pipe 223a is arranged on a concave surface 234a. The heat pipe 223a is formed or arranged up to the connection holding part 233. By forming or arranging up to the connection holding portion 233, the heat generated by the element terminal 226 can be transferred more efficiently.

As shown in FIG. 19(b), a heat pipe 223b is arranged on the concave surface 234b. By arranging the heat pipes 223 on both sides of the connection structure 218, the heat generated by the element terminals 226 can be transferred more efficiently.

In the embodiment shown in FIG. 18, the heat pipe 223 and the like are cooled by the cooling fan 227, but the present invention is not limited to this. For example, as shown in FIG. 20, radiation fins 228 may be formed or arranged so as to be in close contact with heat pipes 223. The heat transferred within the heat pipe 223 is efficiently transferred to the heat radiation fins 228, and the heat transfer and heat radiation effects of the heat pipe 223 are further enhanced.

The radiation fins 228 in FIG. 20 are not formed or placed at the location corresponding to the opening 216. The connecting structure 218 is inserted from the C2 chamber to the C1 chamber side through the opening 216. The opening 216 has a size equal to the cross-sectional area of the connecting structure 218 + α in order to maintain the airtightness of the C1 chamber. Therefore, if the radiation fins 228 are formed or placed on the connection structure 218, they cannot be inserted into the opening 216. Therefore, the radiation fin 228 is not formed or arranged on the side connected to the element terminal 226 of the transistor 117 with respect to the partition wall 217.

Further, as shown in FIG. 21, a circulating water pipe 135 may be formed or disposed within the connection structure 218 to cool the connection structure 218. The connection structure 218 is cooled by the refrigerant flowing in the circulating water pipe, and the heat in the heat pipe 223 is efficiently transferred to the connection structure 218. Therefore, the heat generated at the element terminals 226 is efficiently radiated.

The transistor 117 (semiconductor element 117) in FIG. 38 has two element terminals 226 (element terminal 226a (P), element terminal 226b (N)). However, as shown in FIG. 39, there is also a transistor 117 having three element terminals 226: an element terminal 226a (P), an element terminal 226b (N), and an element terminal 226c. The semiconductor device testing apparatus and semiconductor device testing method of the present invention can test a wide variety of semiconductor devices 117.

The semiconductor element 117 in FIG. 39 has two transistors, a transistor 117m and a transistor 117s, arranged in one package. A collector terminal c of the transistor 117s is connected to the element terminal 226a. The emitter terminal e of the transistor 117s and the collector terminal c of the transistor 117m are connected, and the midpoint is connected to the element terminal 226c. The emitter terminal e of the transistor 117m is connected to the element terminal 226b.

An emitter terminal e1, a gate terminal g1, and a collector terminal c1 are connected to the transistor 117m. An emitter terminal e2, a gate terminal g2, and a collector terminal c2 are connected to the transistor 117s.

FIG. 24 shows the connection state between the transistor 117 (semiconductor element 117) having three element terminals 226 (element terminal 226a (P), element terminal 226b (N), element terminal 226c (O)) and the connection structure 218. It is an illustrated explanatory diagram.

In FIG. 24, the connection between the connection structure 218a and the element terminal 226a and the connection between the connection structure 218b and the element terminal 226b are the same as those explained in FIGS. 22 and 23, and therefore their explanation will be omitted.

In FIG. 24, a heat pipe 223a is formed or arranged in the connection structure 218a, a heat pipe 223b is formed or arranged in the connection structure 218b, whereas a heat pipe 223 is formed or arranged in the connection structure 218c. Not yet. The connection structure 218c is connected to the element terminal 226c. A large current does not flow through the element terminal 226c (O) of the transistor 117. Therefore, the element terminal 226c will not be overheated.

There is no need to form the heat pipe 223 in the connection structure 218c. By forming the connection structure 218c to be thinner than the other connection structures 218 (connection structure 218a, connection structure 218b), connection between the connection structure 218 and the element terminal 226 of the transistor 117 becomes easier. Further, since the space in which the transistors 117 are arranged may be small, the number of transistors 117 that can be mounted on the heating/cooling plate 134 can be increased.

Note that it goes without saying that the heat pipe 223 may be formed or arranged on the connection structure 218c. Other matters are the same as or similar to the embodiments shown in FIGS. 22 and 23, so their explanation will be omitted.
The method for testing a semiconductor device according to the present invention will be explained below. 25, 26, and 30 are explanatory diagrams of the semiconductor device testing method of the present invention in the first embodiment.

Constant current circuit 118 supplies constant current Ic to diode Di of transistor 117. The operational amplifier circuit 116 buffers and outputs the terminal voltage Vi of the diode Di. The terminal voltage Vi is applied to the temperature measurement circuit 115, and the temperature measurement circuit 115 obtains temperature information Tj of the transistor 117 from the terminal voltage Vi and transfers it to the controller 111. The temperature information is output from the connector 213 of the device control circuit board 209 to the mother board 207 and sent to the control circuit board 111 (see FIG. 37, etc.).

In the method for testing the semiconductor device 117 of the present invention, external conditions or test conditions are changed in accordance with deterioration or changes in characteristics of the transistor 117. For example, if the transistor 117 generates heat, the water temperature of the chiller 136 is lowered. Reducing the current flowing through the transistor 117 prevents the deterioration and change in characteristics of the transistor 117 from progressing, and as a result, the life of the transistor 117 is extended. Therefore, it is possible to quantitatively measure and judge the life span and reliability characteristics of the transistor 117 with respect to predetermined setting conditions.

By heating or cooling the circulating water of the chiller 136, the temperature of the transistor 117 is maintained at a specified value or a predetermined value. In addition, the temperature of the transistor, etc. is changed periodically in accordance with the test conditions, and the transistor is cooled and heated at a constant rate. Furthermore, the temperature information Tj of the test transistor is measured, and the chiller 136 is controlled so as to maintain the measured temperature information Tj at a constant value. In addition, in the following description, temperature information Tj will be illustrated and explained.

The gate driver circuit 113 outputs an on-voltage Vg that turns on the gate of the transistor 117 at a set frequency and for a set on-voltage time. As an example, as shown in FIG. 30A, the on/off period of the transistor 117 is tcycle, the on time is ton, and the off time is toff.

The transistor 117 is controlled to be turned on or off based on the on-signal voltage Vgs shown in FIG. 30(a). Gate driver circuit 113 is controlled by gate signal control circuit 112.
The power supply circuit 121 outputs a constant current Id, and the constant current Id is supplied as a test current to the transistor 117.

The transistor 117 is turned on and off by the Vgs signal voltage output from the gate driver circuit 113, and a current Id flows between the channels of the transistor 117 while the transistor 117 is on.

The gate driver circuit 113 has a variable resistance circuit 125 inside. The value of the variable resistance circuit 125 is configured to be set to a predetermined value or in steps between 0 (Ω) and 500 (Ω). The value of the variable resistance circuit 125 may be set using a control signal from the control circuit board (controller) 111 while observing the waveform of the gate terminal g.

A resistor R (not shown) may be placed between the gate terminal g and emitter terminal e or collector terminal c of the transistor 117. By adjusting the value of the resistor R, the slope angle of the rising and falling voltage waveforms of the gate signal can be adjusted.

When the value of the variable resistance circuit 125 is large, the slope of the rising/falling waveform of the gate signal of the transistor 117 applied to the gate terminal of the transistor 117 becomes gentle.

On the other hand, when the resistance value of the variable resistance circuit 125 is small, the slope of the rising/falling waveform of the gate signal becomes steep. By changing the value of variable resistance circuit 125 or setting it to a predetermined value, the on-time of transistor 117 can be adjusted.

The gate driver circuit 113 can set the slope of the rising waveform (rise time Tr) and the slope of the falling waveform (fall time Td) in the gate voltage applied to the gate terminal g of the transistor 117. By separately adjusting the rise time Tr and fall time Td, the on time of the transistor 117, etc. can be adjusted as desired.

The resistance value of the variable resistance circuit 125 is set by the control circuit board (controller) 111. The setting is not limited to a constant value. The slope of the rising waveform (rise time Tr) and the slope of the falling waveform (fall time Td) of the gate driver circuit 113 may be changed. The resistance value when the gate signal rises and the resistance value when it falls may be changed. Further, the resistance value may be variably controlled in real time. By variably controlling the variable resistance circuit 125, the on time of the transistor 117 is stabilized.

When the resistance value at the rise of the gate signal is reduced, the waveform of the on-voltage applied to the gate terminal of the transistor 117 becomes steeper, and the transistor 117 is turned on at high speed. When the resistance value at the rise of the gate signal is increased, the waveform of the on-voltage applied to the gate terminal of the transistor 117 becomes gentler, and the transistor 117 is turned on gradually.

If the resistance value at the time of the fall of the gate signal is reduced, the waveform of the on-voltage applied to the gate terminal of the transistor 117 becomes steeper, and the transistor 117 is turned off at high speed. When the resistance value at the time of the fall of the gate signal is increased, the waveform of the on-voltage applied to the gate terminal of the transistor 117 becomes gentler, and the transistor 117 is turned off gradually.

As described above, the value of the variable resistance circuit connected to the gate terminal of the transistor 117 or the rise time/fall time of the gate driver circuit 113 can be controlled, adjusted, or set. Therefore, as a function of the gate driver circuit 113, the inrush current Is and surge voltage Vs generated in the transistor 117 can be varied or changed.

It goes without saying that the operation of the transistor 117 not only controls the on-voltage of the gate terminal of the transistor 117, but also changes or sets the value of the constant current Id or voltage Vm supplied to the transistor 117 by the power supply circuit 121.

The variable resistance circuit 125 of the gate driver circuit 113 is controlled by the control circuit board (controller) 111. The period time tcycle, on time ton, or off time toff of the gate signal output by the gate driver circuit 113 shown in FIG. 30 is controlled by the gate signal control circuit 112, and the gate signal is applied to the gate terminal of the transistor 117. Further, the gate signal control circuit 112 is controlled by a control circuit board (controller) 111.

14, FIG. 25, FIG. 26, FIG. 27, FIG. 29, etc., the resistance value of the variable resistance circuit 125 of the gate driver circuit 113 is assumed to be variable, but it is not limited thereto. For example, it goes without saying that the variable resistance circuit 125 may be an external resistor, and the resistor may be connected to the gate terminal of the transistor 117 through a connector (not shown) or the like.
The value of the resistor to be connected is set by observing the waveform of the gate terminal of the transistor 117 and the waveform of the channel current Id.

14, FIG. 25, FIG. 26, etc., a constant current circuit 118 is connected between the collector terminal c and the emitter terminal e of the transistor 117. Constant current circuit 118 passes a predetermined constant current Ic. The constant current Ic is for monitoring the temperature of the transistor 117.

Note that since this specification will be described using an IGBT as an example, the terminals of the transistor 117 are a gate terminal g, a collector terminal c, and an emitter terminal e. In the case of the MOS transistor 117, the terminals of the transistor 117 are a gate terminal g, a drain terminal d, and a source terminal s.

A body diode or a channel diode Di is formed in the transistor 117. Note that the diode Di may be a diode of another semiconductor chip mounted on the semiconductor chip in which the transistor 117 is formed.

As the diode Di, a diode (parasitic diode) formed secondarily when forming the transistor 117 may be used. A parasitic diode is formed secondarily by the layer structure of the transistor 117. Structurally, the diode Di is formed near the channel portion of the transistor 117.

The diode Di may be any element as long as it does not operate while the transistor 117 is operating. For example, the present invention is not limited to diodes, and it goes without saying that a diode-connected transistor may be used.

Further, the device is not limited to semiconductors such as diodes, but may also be devices such as resistors. By applying a constant current Ic to a device such as a resistor, the terminal voltage of the resistor is measured. This voltage is measured as voltage Vi.

As described above, the element for acquiring temperature may be not only a device such as a semiconductor but also a device such as a resistor. In other words, any device can be applied as long as it is a device that can obtain a voltage value by passing a current or a device that can obtain a current value by applying a voltage.

The resistance value of the diode Di changes as the transistor 117 generates heat. When a constant current Ic is passed through the diode Di, the voltage between the terminals of the diode Di changes in proportion to the change in the resistance value of the diode Di. By monitoring or measuring the voltage between the terminals, the temperature of the transistor 117 or a change in temperature can be known.
In order to monitor the temperature of the transistor 117 from the voltage of the diode Di, it is necessary to obtain the temperature coefficient in advance.

The temperature coefficient is determined by setting the transistor 117 at a predetermined temperature in a constant temperature bath, passing a constant current Ic through the diode Di, and measuring the terminal voltage of the diode Di. By changing the predetermined temperature and measuring the terminal voltage of the diode Di, the terminal voltage of the diode with respect to temperature can be obtained. Therefore, the temperature coefficient K of the transistor 117 can be determined from the terminal voltage of the diode Di with respect to temperature.

Although the temperature coefficient K may differ depending on each production lot of the transistor 117, it generally shows a constant value depending on the production lot. Therefore, if the transistor 117 to be tested is sampled from each production lot and the temperature coefficient K is determined, it can be used for the temperature coefficient K of other transistors 117 as well.

In order to obtain the temperature coefficient K with high accuracy, the temperature coefficient K of each transistor 117 is individually measured and tested even in the same lot. Measurement of the temperature coefficient K is not limited to the use of a constant temperature bath. For example, the temperature coefficient K is obtained by changing the temperature of water flowing through a heat sink in which the transistor 117 is mounted.

During testing, a test current Id is applied to the transistor 117 intermittently. Immediately after the test current Id is turned off, or after a short predetermined period of time has passed after the test current Id is turned off, a constant current Ic for temperature measurement is caused to flow from the constant current circuit 118.

In order to prevent the transistor 117 from generating heat due to the constant current Ic, or to avoid the influence of the constant current Ic, the constant current Ic is set to a sufficiently smaller current value than the constant current Id flowing through the channel of the transistor 117. . The constant current Id is a current that does not generate heat that affects temperature measurement.

Specifically, the constant current Ic is set to 1/1000 or less of the current Id flowing through the transistor 117 during the test. Preferably, the current Ic flowing through the transistor 117 is set to be greater than or equal to 1×10 ⁶ and less than or equal to 1×10 ⁴ of the current Id. The constant current Ic should be 0.1 mA or more and 100 mA or less.

The temperature coefficient K is determined by varying the channel current Id and measuring the diode Di voltage (voltage between the collector and emitter terminals of the transistor 117). The obtained temperature coefficient K is stored in the temperature measurement circuit 115.

When measuring temperature, if the diode Di is formed in the same chip as the transistor 117, the saturation voltage Vn may change depending on the gate voltage Vgs. The gate voltage Vgs is preferably zero (0) voltage or negative voltage (minus voltage).

As shown in FIG. 13, the control circuit board (controller) 111 controls the chiller 136 based on the temperature information Tj. The chiller 136 adjusts the temperature of circulating water (circulating solution) and adjusts the temperature of the heating/cooling plate 134 .

In the above embodiments, the temperature coefficient K is determined in advance, but the semiconductor testing method of the present invention is not limited to this. Note that temperature information Tj of the transistor 117 is obtained from the temperature coefficient, diode terminal voltage, and the like.
The transistor 117 and the heating/cooling plate 134 are arranged in close contact with each other so that the temperature of the heating/cooling plate 134 substantially matches that of the transistor 117 .

The control circuit board (controller) 111 controls the chiller 136 to bring the temperature of the heating/cooling plate 134 to a predetermined temperature, applies a constant current Ic to the transistor 117, and measures the terminal voltage of the diode Di.

The temperature coefficient K is determined from the measurement results. The temperature of the heating/cooling plate 134 is set to a plurality of temperatures, the temperature coefficient K at each temperature is determined, and the accuracy of the temperature coefficient value is further improved from the results.

The temperature coefficient K is determined by heating the transistor 117 to a predetermined temperature using the heating/cooling plate 134, passing a constant current Ic through the diode Di, and measuring the terminal voltage. By changing the predetermined temperature and measuring the terminal voltage of the diode Di, the terminal voltage of the diode Di with respect to temperature can be obtained. Therefore, the temperature coefficient K of the transistor 117 can be determined from the terminal voltage of the diode Di with respect to temperature.

When testing the transistor 117, a constant current Ic is passed through the diode Di when the channel current Id is not flowing. That is, when the transistor 117 is not turned on, a constant current Ic is caused to flow and the voltage between the terminals of the diode Di is measured.

The operational amplifier circuit (buffer circuit) 116 outputs the terminal voltage Vi (terminal c-terminal e) of the diode Di. Note that the operational amplifier circuit 116 is not limited to one composed of operational amplifier elements. Any type with high input impedance and low output impedance may be used.
The temperature measurement circuit 115 obtains temperature information Tj of the transistor 117 under test from the held temperature coefficient K and voltage Vi.

The obtained temperature information Tj is sent to the control circuit board (controller) 111. When the temperature information Tj exceeds a predetermined set value, the control circuit board (controller) 111 determines that the transistor 117 is in a predetermined stress state or deteriorated state, and changes the control of the test or stops the test. .

The location where the transistor deteriorates during testing is often the junction within the transistor 117. The semiconductor itself does not deteriorate, but the junction (bonding, die bond, etc.) of the transistor 117 deteriorates, and the resistance value of the junction increases. As the resistance value increases, the voltage Vce increases, heat is generated, and the temperature of the transistor 117 increases.

When a semiconductor deteriorates, it is often due to deterioration of the gate oxide film (insulating film) of the transistor 117. When deterioration of the gate oxide film occurs, the oxide film (insulating film) becomes short-circuited, and the voltage Vce decreases. Alternatively, the transistor 117 is turned off, no current flows through the transistor 117, and the voltage Vce rises to the maximum value of the power supply voltage.

At the start of the test, the temperature information Tj changes between the lowest temperature T1 and the highest temperature T2. When stress is applied to the transistor 117 during a test, the Vce voltage of the transistor 117 changes, and normally the temperature information Tj changes in the direction of increasing.
Therefore, as shown in FIG. 31(c), the lowest temperature rises from the temperature T1, and the highest temperature approaches the temperature information Tm (Tjmax).
In the semiconductor testing method of the present invention, the test is terminated under any of the following conditions.
- When temperature information Tj falls outside of a predetermined range.
- When the channel voltage Vce deviates from the predetermined voltage range.
・When the thermal resistance is outside the specified range.

In the embodiments shown in FIGS. 14, 25, 26, 27, 28, and 29, the switch circuit Ssa124a and the switch circuit Sab124b use switch circuit symbols. For the switch circuit Ssa124a and the switch circuit Sab124b, any element can be used as the switch circuit as long as it has a small resistance (on resistance) when closed (on). Examples include transistors, mechanical relays, phototransistors, photodiode switches, and the like.

FIG. 26 is an equivalent circuit diagram of a semiconductor device testing apparatus according to the first embodiment of the present invention. In this embodiment, the switch circuit Ssa and the switch circuit Sab use a power MOSFET 124 as shown in FIG. 26. A power MOSFET has a small voltage (Vsd) between channels.

It should be noted that something other than a power MOSFET may be used as the switch circuit. It goes without saying that the switch circuit Ssa and the switch circuit Sab may be not only power MOSFETs but also power transistors or the like. Other examples include electromagnetic relays and electromagnetic switches.

The on-time channel voltage (Vsdb) of the power MOSFET 124b is selected to be equal to or lower than the on-time channel voltage (Vsda) of the power MOSFET 124a. That is, the channel voltage (Vsdb) when the power MOSFET 124b is on is set to be smaller than the channel voltage (Vsda) when the power MOSFET 124a is on. This is to completely short-circuit the terminals of the power supply circuit 121 when the switch circuit 124b is turned on, so that the current Im can stably flow.
The above matters also apply when the switch circuit 124 is a power transistor or the like. In the case of power transistor 124, the channel voltage is Vce.
By turning on the switch circuit 124a, the current Id output from the power supply circuit 121 can be supplied to the transistor 117 as the test current Id.

The switch circuit 124 is mounted on the switch circuit board 201. The switch circuit 124 is connected to a conductor plate 204 (metal plate, conductive plate). The conductor plate 204 is, for example, a plate made of copper and has a thickness of 5 mm and a width of 50 mm. The length has the width of the circuit board plus the width for connecting the fork plug 205.

In the embodiment of the present invention, the fork plug 205 and the conductive plate 204 are brought into contact and electrically connected, but the present invention is not limited to this. Any device may be used as long as it can change between an electrically connected state and a non-connected state by mechanical operation. Further, any configuration may be used as long as the connected state can be stably maintained.

For example, instead of the fork plug 205, a rotary connector, rotary joint, high current connector, etc. may be used. Instead of the conductor plate 204, a rotary connector, a rotary joint, a large current connector, a cylindrical conductor bar, a square conductor bar, a comb-shaped conductor plate, etc. may be used instead.

Although described as a conductor plate 204 in this specification and the drawings, it is not limited to a plate, and may be in the shape of a rod. It may have any shape as long as it can be joined to a structure such as the fork plug 205. For example, it may be a structure such as a socket or a connector. Alternatively, the conductor plate 204 may be shaped like a fork plug, and the fork plug 205 may be connected to the fork plug.

Although the fork plug 205 will be described as being inserted into a component or structure that separates a space, such as the partition wall 214, the fork plug 205 is not limited thereto. For example, a fork plug 205c may be connected to the conductor plate 204b, and the fork plug 205c may be inserted through the partition wall 214 to establish electrical connection with the emitter terminal e of the transistor 117.

FIG. 36 illustrates the fork plug 205 and the connection (contact) state between the fork plug 205 and the conductor plate 204. Two conductor plates 204 are attached to the switch circuit board 201. The switch circuit board 201 has a whole surface ground layer (not shown), and the whole surface ground layer and the conductor plate 204 are thermally connected. The heat of the conductor plate 204 is radiated through the entire surface ground layer. The conductor plate 204 and the switch circuit board 201 are screwed together.

Note that although the contact portion 220 is shown as being disposed or formed directly on the fork plug 205, the present invention is not limited thereto. For example, as explained in FIG. 7 etc., the contact part 220 may be provided with a spring 236, a spring hole 239, a position fixing screw 237, a screw hole 238, etc., and the contact part 220 may be configured to slide. Needless to say.

The switch circuit 124 is connected to two conductor plates. As shown in FIG. 26, when the switch circuit 124 is a MOS transistor, its drain terminal and source terminal are connected to different conductor plates 204. If the switch circuit 124 is a bipolar transistor, its collector terminal and emitter terminal are connected to different conductor plates 204. When the switch circuit 124 is turned on (conducted), the two conductor plates 204 are electrically connected. An IGBT can also be used as the switch circuit 124.

As a constituent material of the contact portion 220 of the fork plug 205, platinum, gold, silver, tungsten, copper, nickel, or an alloy of a combination thereof is used. It is also preferable to use silver-oxide contact materials (Ag+ZnO, Ag+SnO ₂ , Ag+SnO ₂ In ₂ O ₃ , Ag+, Ag+SnO ₂ Sn ₂ Bi ₂ O ₇ ).

The fork plug 205 and the conductor plate 204 are electrically connected by mechanically fitting them together. When the U-shaped portion of the fork plug 205 is inserted into the conductive plate 204, the U-shaped portion expands slightly, and the fork plug 205 and the conductive plate 204 are properly joined. By properly joining or fitting, the electrical resistance of the connection becomes extremely low, and even if a large current flows through the connection, no heat generation or voltage drop will occur.

A connecting bolt 219 is attached to the fork plug 205. Connection wiring 211 is connected to connection bolt 219 . A cross section taken along AA' in FIG. 36(a) is shown in FIG. 36(b). The conductor plate 204 and the fork plug 205 are brought into contact with each other at a contact portion 220a and a contact portion 220b formed on the fork plug 205. The surface of the contact portion 220 is plated with silver. The contact portion 220 is made of phosphor bronze and nickel alloy.
Note that the connection bolt 219 is not limited to a bolt, and may be any bolt that can electrically connect the fork plug 205 and the wire.
The surface of the conductor plate 204 is silver-plated at least at the portion that contacts the fork plug 205.

FIG. 16 is a configuration diagram of a semiconductor device testing apparatus according to the present invention. The connection structure 218a is inserted into the opening 216a of the partition 217, and the connection structure 218b is inserted into the opening 216b of the partition 217.

The connection structure 218a is connected to the device terminal 226a of the transistor 117, and the connection structure 218b is connected to the device terminal 226b of the transistor 117. A circulating water pipe 135 is incorporated into the heating/cooling plate 134 . A thermocouple 316 is placed in the package of the transistor 117 to measure or obtain the temperature of the transistor 117 during the test.

A connector 202 is connected to a terminal of the transistor 117, and a signal wiring 222 connected to the connector 202 is connected to a sample connection circuit 203. The signal wiring 235 of the sample connection circuit 203 is connected to the device control circuit board 209 via the connector 208.

The fork plug 205 and the conductor plate 204 are brought into contact by inserting the fork plug 205 through the opening 216 of the partition wall 214, as shown in FIG. 16 and the like. At the time of contact, the U portion of the fork plug 205 is spread out by the conductor plate 204 and is firmly contacted.

FIG. 15 shows a layout diagram of each component of the semiconductor device testing apparatus of the present invention. The housing 210 of the semiconductor device testing apparatus is separated into three parts. The lower part of the housing is separated into a room A and a room B. A power supply device 132 is arranged in the A room. Room A and room B are separated by a partition wall 215.

Each room is shielded. The power supply device 132, the switch circuit board 201, and the transistor 117 generate large noise by repeating operation/non-operation. Noise causes malfunctions of circuit boards, etc., so malfunctions are prevented by shielding. Shielding is achieved by placing conductive plates, metal plates, or metal films around each chamber.

In the C1 chamber, a heating/cooling plate 134, a circulating water pipe 135, etc. shown in FIG. 13 are arranged, and a transistor 117 to be tested is arranged on the heating/cooling plate 134.

A partition wall 214 is formed between the C1 chamber and the A and B chambers. A water leakage sensor (not shown) is arranged around the heating and cooling plate of the C1 chamber. When circulating water (cooling medium) or the like leaks, a water leakage sensor is activated to stop the semiconductor device testing apparatus or issue an alarm.

Additionally, a drainage groove is formed around the heating and cooling plate, and when circulating water (cooling medium) leaks from the heating and cooling plate, the circulating water (cooling medium) flows into the drainage groove. It is configured to be discharged to the outside.
As described above, the partition wall 214 is configured so that even if the circulating water pipe 135 is damaged, circulating water (cooling medium) etc. will not leak into the lower chambers A and B.

A partition wall 215 is formed between the A room where the power supply device 132 is placed and the B room where the drive circuit system is placed. Electrostatic shield plates are arranged on the partition walls 214, 215, and 217 to shield noise from the power supply device 132, and the noise is not applied to the drive circuit system in the B room.

In the embodiment of the present invention, it will be explained that the fork plug 205 is inserted from the C2 chamber and connected to the conductor plate 204 of the B chamber. The operation of pushing the fork plug 205 from the upper side to the lower side is easy. However, the present invention is not limited to this. For example, the conductor plate 204 may be arranged in the C2 chamber, and the fork plug 205 may be inserted from the B chamber to electrically connect.
Further, the connection structure 218 is inserted from the C2 chamber, and the element terminal 226 of the semiconductor element 117 and the connection structure 218 are connected.

As illustrated in FIG. 15 and the like, the connection structure 218 is inserted from the C2 chamber into the C1 chamber and electrically connected to the element terminal 226 of the transistor 117. Further, the fork plug 205 is inserted from the C2 chamber into the B chamber to electrically connect the fork plug 205 and the conductor plate 204. The transistor 117 is fixed to the heating/cooling plate 134, and the switch circuit board 201 is fixed at the mother board 207 position. The connection structure 218 and the fork plug 205 are electrically connected by a connection wiring 211.

The location of the opening 216 in the connection structure 218 can be selected to select the transistor 117 to be tested. By selecting the opening into which the fork plug 205 is inserted, the switch circuit board 201 to be controlled can be easily selected and the test method and test conditions can be changed. Therefore, in the present invention, by using the connection structure 218 and the fork plug 205, it is possible to easily select the transistor 117 and change the test method etc. in a short time.

Note that the partition walls 214, 215, and 217 are exemplified by wall-like structures, plate-like structures, film-like objects, mesh-like objects, wire mesh-like objects, and the like. Examples include phenolic resins (phenol resins, phenol-formaldehyde resins, and carbonic acid resins). The partition wall may be any material that separates the first part and the second part of the semiconductor device testing apparatus.

As shown in FIG. 37, a connector 213 is attached to the motherboard 207. A control circuit board 111, a device control circuit board 209, and a switch circuit board 201 are attached to the connector of the mother board 207. The switch circuit boards 201 prepared according to the number of transistors 117 to be tested can be easily realized by changing the number of switch circuit boards 201 attached to the mother board 207.

Temperature information Tj, voltage Vi, a control signal for the variable resistance circuit 125, a control signal for the constant current circuit 118, and the like are transmitted to the motherboard 207. Further, power wiring and ground wiring for each circuit are formed and supplied to each circuit board via a connector 213.
The conductor plate 204 is arranged so as to protrude from the switch circuit board 201. A fork plug 205 is connected to this protruding portion.

The fork plug 205a is connected to the conductor plate 204a of the switch circuit board 201a. The power supply wiring 212 is connected to the switch circuit board 201a through the opening 216 of the partition wall 215. The fork plug 205d is connected to the conductor plate 204c of the switch circuit board 201b. The power supply wiring 212 is connected to the switch circuit board 201b through the opening 216 of the partition wall 215. The fork plug 205b is connected to the conductor plate 204b of the switch circuit board 201a. The power supply wiring 212 is connected to the switch circuit board 201a through the opening 216 of the partition wall 215.

As shown in FIGS. 14, 25, etc., a switch circuit 124a is arranged between the conductor plate 204d and the conductor plate 204c of the switch circuit board 201b, and short-circuits the conductor plate 204d and the conductor plate 204c. By shorting, the current Id output from the power supply circuit 121 is supplied to the transistor 117 as the test current Id.

A switch circuit 124b is arranged between the conductor plate 204a and the conductor plate 204b of the switch circuit board 201a, and when the switch circuit 124b is turned on, the conductor plate 204a and the conductor plate 204b are short-circuited. Due to the short circuit, the current Id output by the power supply circuit 121 flows to the ground as a discharge current Im, and the channels of the transistor 117 are short-circuited. By short-circuiting the channels, no overvoltage or overcurrent is applied to the transistor 117.

A fork plug 205 is connected to the conductor plate 204. A fork plug 205c is connected to the conductor plate 204b. A fork plug 205b is connected to the conductor plate 204a. Furthermore, a fork plug 205e is connected to the conductor plate 204d. A fork plug 205d is connected to the conductor plate 204c.

FIG. 36 is a configuration diagram of the fork plug 205. FIG. 36(a) shows a state in which the conductor plate 204 attached to the switch circuit board 201 and the fork plug 205 are coupled. FIG. 36(b) shows the coupled state of the conductor plate 204 and the fork plug 205 when the cross section taken along the line AA' in FIG. 36(a) is viewed from the direction of the arrow.

The material of the fork plug 205 is a metal such as aluminum. In addition, the surface is nickel-treated and silver-plated. The fork flag 205 has a thread groove formed therein, and is configured so that the connection wiring 211 can be attached to the fork plug 205 with a connection bolt 219.

The convex contact portion 220 is made of phosphor bronze or copper alloy. Further, the surface of the contact portion 220 is plated with silver. The insertion force of the fork plug 205 into the conductor plate 204 is configured to be 40 or more and 60N or less.

For the contact portion 220, platinum, gold, silver, tungsten, copper, nickel, or an alloy of a combination thereof is used. It is also preferable to use silver-oxide contact materials (Ag+ZnO, Ag+SnO ₂ , Ag+SnO ₂ In ₂ O ₃ , Ag+, Ag+SnO ₂ Sn ₂ Bi ₂ O ₇ ).

Although two switch circuit boards 201 are shown in FIG. 37, two or more switch circuit boards 201 are required depending on the number of transistors 117 to be tested, and the switch circuit board 201 is connected to the connector 213 of the mother board 207. be done.

As shown in FIG. 16, the fork plug 205c is inserted through the opening 216 of the partition wall 214 provided between the C2 chamber and the B chamber, and the conductor plate 204b and the fork plug 205c are connected. The transistor 117 to be tested and the heating/cooling plate 134 are arranged in the C1 room, and the drive circuit for testing the transistor 117 and the like are arranged in the B room. Since the C1 chamber, the C2 chamber, and the B chamber are separated by the partition wall 214, even if the refrigerant liquid leaks from the heating/cooling plate 134, it will not leak into the B chamber. Note that a water leakage sensor (not shown) is arranged around the heating and cooling plate 134. Furthermore, a groove is formed to discharge the cooling liquid to the outside of the test apparatus in the event that the cooling liquid flows out.
An electrostatic shield plate is disposed on the partition wall 214 to prevent the drive circuit system in the B room from malfunctioning due to noise generated from the transistor 117.

Since the current flowing through the transistor 117 to be tested is as large as several hundred amperes, the thickness of the connection wiring 211 used is also large. Therefore, the connection wiring 211 does not have sliding properties, and the connection wiring 211 is hard, making it difficult to change the connection of the connection wiring 211.

In the semiconductor device testing apparatus of the present invention, the switch circuit board 201 can be connected to the fork plug 205 inserted from the C2 chamber. Therefore, to change the connection between the transistor 117 and the switch circuit board 201 used under test conditions, there is no need to change the connection of the connection wiring 211, and only the position of the opening 216 into which the fork plug 205 is inserted needs to be changed. Further, in the switch circuit board 201, only the position of the connector 213 connected to the mother board 207 needs to be changed.

As shown in FIGS. 14, 15, 25, 26, 28, etc., the connection wiring 211b connected to the transistor 117 is connected to the fork plug 205c. The connection wiring 211a connected to the transistor 117 is connected to the fork plug 205e.

Even if there are a plurality of transistors 117 to be tested and only one switch circuit board 201a is used, it is sufficient for the purpose. This is because the output current Id of the power supply circuit 121 may be made to flow as Im to the ground line.

The switch circuit board 201b requires the number of transistors 117 to be tested. For example, if there are 12 transistors 117 to be tested, it is preferable to prepare 12 switch circuit boards 201b. It is advantageous in terms of cost that the switch circuit board 201a and the switch circuit board 201b have the same specifications.

A plurality of transistors and the like as the switch circuit 124 are mounted on the switch circuit board 201 . The larger the number of switch circuits 124, the smaller the impedance that short-circuits the two conductor plates 204. The number of switch circuits 124b to be mounted on the switch circuit board 201a is determined so that the on-resistance of the switch circuit 124b is smaller than the on-resistance of the transistor 117 to be tested.

34 and 35 illustrate a state in which the fork plug 205 is inserted into the opening 216 of the partition wall 214. 34 is a view of the partition wall 214 seen from the front surface, and FIG. 35 is a view of the partition wall 214 seen from the back surface.

As an example, a fork plug 205b and a plurality of fork plugs 205c (fork plugs 205c1 to 205c5) are connected to the conductor plate 204b in FIG. 34. A fork plug 205e1 is connected to the conductor plate 204d1, a fork plug 205e2 is connected to the conductor plate 204d2, a fork plug 205e3 is connected to the conductor plate 204d3, a fork plug 205e4 is connected to the conductor plate 204d4, and a fork plug 205e5 is connected to the conductor plate 204d5.

A transistor 117 to be tested is connected between the fork plug 205c and the fork plug 205e. Switch circuit boards 201b corresponding to the number of transistors 117 to be tested are mounted on the mother board 207. The opening 216 is formed corresponding to the position of the conductor plate 204 of the switch circuit board 201.

Although not shown, large noise is generated when the switch circuit 124 of the switch circuit board 201 is turned on and off. As a countermeasure against this, a metal plate is placed between the switch circuit boards 201, and the metal plate is grounded.

In each drawing, one switch circuit 124 is shown on the switch circuit board 201. However, in reality, a plurality of switch circuits 124 are arranged between the conductive plates 204. By arranging a plurality of switch circuits 124 on the switch circuit board 201, it is possible to short-circuit between the conductor plates 204 (for example, between the conductor plates 204c and 204e) with low resistance.

Heat generated by the switch circuit 124 is radiated to the conductive plate 204. Further, a heat sink is attached to the switch circuit 124. The ground terminal of the switch circuit 124 is connected to the ground of the switch circuit board 201, and heat is also radiated through the ground copper foil.

As illustrated in FIG. 15, two conductor plates 204 are attached to the switch circuit board 201, and the switch circuit 124 is arranged so as to short-circuit the two conductor plates 204. Moreover, FIG. 25 is an equivalent circuit diagram of the semiconductor device testing apparatus of the present invention in the first embodiment.

As shown in FIGS. 14, 15, 16, etc., a conductor plate 204a and a conductor plate 204b are attached to the switch circuit board 201a. The conductor plate 204a is connected to a fork plug 205a. The fork plug 205a is connected to the output terminal of the power supply circuit 121. The conductor plate 204b is connected to a fork plug 205b. The fork plug 205b is connected to the ground terminal of the power supply circuit 121.

When the switch circuit 124b is turned on, the output terminals of the power supply circuit 121 are short-circuited, and a short-circuit current Im flows. Therefore, the output current of power supply circuit 121 is not supplied to transistor 117. When the switch circuit 124b is open, the output current Id of the power supply circuit 121 is supplied to the transistor 117.

A conductive plate 204c and a conductive plate 204d are attached to the switch circuit board 201b. The conductor plate 204c is connected to the fork plug 205d. The fork plug 205d is connected to the output terminal of the power supply circuit 121. The conductor plate 204d is connected to the fork plug 205e. The fork plug 205e is connected to the collector terminal of the transistor 117 to be tested.

As shown in FIGS. 15, 16, 34, 35, etc., the fork plug 205e is inserted into an opening 216 formed in the partition wall 214, and is coupled to the conductor plate 204d. Further, the fork plug 205c is inserted into an opening 216 formed in the partition wall 214, and is coupled to the conductor plate 204d.

A switch circuit 124a is arranged on the switch circuit board 201b, and when the switch circuit 124a is turned on, the output current Id from the power supply circuit 121 is supplied to the transistor 117 as a test current Id flowing through the transistor 117.

The switch circuit board 201b is placed in the B room of the housing 210, but the fork plug 205 inserted from the opening 216 of the partition wall 214 from the C2 room connects the switch circuit board 201b and the transistor 117 to be tested electrically. Connected.

As shown in FIGS. 15, 16, 34, 35, etc., the fork plug 205 and the conductor plate 204 are connected. In FIG. 16, the switch circuit boards 201 are illustrated as being arranged in parallel. In reality, the switch circuit boards 201 are inserted and arranged in parallel in a board rack. A motherboard is arranged on the side of the board rack, and control signals to each circuit board are applied from the motherboard.

FIG. 30 is an explanatory diagram of the semiconductor device testing method of the present invention in the first embodiment. In FIG. 30, Vgs is a gate signal applied to the gate terminal of the transistor 117 to be tested. Id is a current flowing through the transistor 117 during the test. For ease of explanation, it is assumed that a constant current Id flows through the transistor 117 when it is on.

St1 in FIG. 30(c) is a timing signal for causing current Ic to flow through the diode Di, and when St1 is at H level, current flows through the diode Di of the transistor 117. The operational amplifier circuit 116 acquires the voltage between the terminals of the diode Di, and the temperature measurement circuit 115 converts the voltage between the terminals into temperature information Tj. The temperature information Tj is sent to the control circuit board (controller) 111, and the control circuit board (controller) 111 tests the transistor 117 (semiconductor element 117) according to the temperature information Tj.

The constant current Id is a current flowing through the transistor 117 to be tested, and is a current output by the power supply circuit 121. St1 and St2 are the time during which a measuring current is passed through the temperature measuring diode or the time during which the temperature is measured.
30(e) Ssa is an on/off signal of the switch circuit 124a, and FIG. 30(f) Sab is an on/off signal of the switch circuit 124b.

In FIG. 30(g), Vce indicates the voltage at the c terminal of the transistor 117 (channel voltage of the transistor 117), and temperature information Tj indicates the measured temperature change of the transistor 117.

As illustrated in FIG. 30(a), a gate signal Vgs is applied from the gate driver circuit 113 to the gate terminal g of the transistor 117. The gate signal Vgs has a cycle time tcycle and an on time ton. The cycle time tcycle and the on time ton can be set to arbitrary values by the gate signal control circuit 112. Further, the on-voltage Vg can also be set to an arbitrary voltage.

FIG. 30(d) St2 is a timing signal for causing current Ic to flow through the diode Dsa and the diode Dsb in the embodiment shown in FIG. When St2 is at H level, current flows through the diode Dsa or Dsb of the transistor 117. This is a case where temperature information Tj is obtained by flowing a constant current Ic through a device (diode) independent of the transistor 117.

The operational amplifier circuit 116 acquires the voltage between the terminals of the diode Dsa or Dsb, and the temperature measurement circuit 115 converts the voltage between the terminals into temperature information Tj. The temperature information Tj is sent to the control circuit board (controller) 111, and the control circuit board (controller) 111 tests the transistor 117 based on the temperature information Tj. Note that matters related to St2 will be explained with reference to FIG. 27 and the like.

For ease of understanding, the description will be made assuming that the measured temperature information Tj changes between T1 and T2, as shown in FIG. 30(h). Temperature information Tj becomes high when the transistor 117 is energized, and decreases when the current flowing is stopped. Furthermore, the temperature information Tj changes as the characteristics of the transistor 117 change.

FIG. 30(e) Ssa shows the timing of the on/off control signal of the switch circuit Ssa. When Ssa becomes Von, the switch circuit Ssa is closed (turned on). In the case of 0, the switch circuit Ssa is open (off) and the application of current or voltage is cut off.

FIG. 30(f) Ssb shows the timing of the on/off control signal of the switch circuit Ssb. When Ssb becomes Von, the switch circuit Ssb is closed (turned on). In the case of 0, the switch circuit Ssb becomes open (off).

FIG. 30(g) Vce is the channel voltage (voltage between the emitter terminal and collector terminal) of the transistor 117. As the transistor 117 is turned on and off, a surge voltage and a surge current are generated, and as the on-resistance of the transistor 117 changes, the Vce waveform changes temporally in a complex manner. Further, as the current Ic flows through the diode Di, the Vce waveform of the transistor 117 changes.

In this specification and the drawings, in order to facilitate explanation or drawing, it is assumed that when the transistor 117 is on, the voltage is Vn, and when the transistor 117 is off, the voltage is Ve.
The gate signal is applied to the gate terminal of the transistor 117 to be tested with a period tcycle, an on time ton, and an off time toff.

When the transistor 117 is an N-channel transistor, the gate signal Vgs has a ground voltage of 0 (V) as an off voltage, and Vg as an on voltage. When the transistor 117 is a P-channel transistor, the on-voltage potential and the off-voltage potential are changed.

During the tn2 period before turning on the transistor 117, the Vt voltage is set to the negative side of the off-voltage. Further, during the tn1 period after the transistor 117 is turned off, the Vt voltage is set to the negative side of the off voltage.
The Vt voltage is lower than 0 (V) and higher than -4 (V). Therefore, Vt is a voltage of -4 (V) or more and lower than 0 (V).

Note that when the transistor 117 is SiC, the off-voltage is set to Vt voltage, and when the transistor 117 is an IGBT, the off-state voltage is set to 0 (V). As described above, the semiconductor device testing apparatus of the present invention is configured so that the off-voltage supplied to the transistor 117 can be changed depending on the type of the transistor 117 to be tested.

When the Vt voltage is applied, St1 (St2) is set to H level and the temperature of the transistor 117 is measured. A constant current Ic is passed through the diode Di during the period when the Vt voltage is applied. Further, a constant current Ic is applied during the H level period of St1 (St2).

By applying the Vt voltage to the gate terminal of the transistor 117, the off state of the transistor 117 is stabilized, and temperature information Tj can be measured stably. Furthermore, noise is less likely to occur when measuring the temperature information Tj, and the accuracy of measuring the temperature information Tj is improved.

By applying the Vt voltage to the gate terminal of the transistor 117, the leakage current of the transistor 117 is reduced, the measurement accuracy of the Vi voltage is improved, and the measurement is stabilized.

The gate signal Vgs is set to the Vt voltage at times tn1 and tn2. As an example, the times tn1 and tn2 are 0.2 msec or more and 2 msec or less. Transistor 117 is turned off at 0 (V).

Therefore, three voltages, Vg, 0 (V), and Vt, are applied to the gate terminal g of the transistor 117. During the period when Vt is being applied, a current is caused to flow through the diode Di of the transistor, and temperature information Tj is measured.

When a constant current Ic is caused to flow through the diode Di, the switch circuit Ssa is turned off to control so that the current from the power supply circuit 121 is not applied to the transistor 117.

By flowing a constant current Ic through the diode Di, the terminal voltage of the diode Di is obtained, and the operational amplifier circuit 116 outputs a voltage Vi corresponding to the terminal voltage. The Vi voltage is input to the temperature measurement circuit 115, and the temperature measurement circuit 115 obtains temperature information Tj corresponding to the temperature of the transistor 117.

The temperature information Tj is transferred to the control circuit board (controller) 111, and the control circuit board (controller) 111 controls the test of the transistor 117 (semiconductor element 117), such as continuing or stopping the test of the transistor 117, changing conditions, etc., based on the temperature information Tj. Control the exam.

FIG. 30(e) Ssa is a timing signal for controlling on/off of the switch circuit 124a. FIG. 30(f) Ssb is a timing signal for controlling on/off of the switch circuit 124b.

The switch circuit 124a turns on with a delay of tm2 after the Vgs signal of the transistor 117 becomes Vg. The tm2 time is configured so that it can be changed and set by a control circuit board (controller) 111.

The switch circuit 124b is turned on tb2 hours before the switch circuit 124a is turned on. The on state of the switch circuit 124b is maintained until tb1 time after the switch circuit 124a is turned on. The tb2 time and tb1 time can be changed and set independently.
In particular, the setting of tb1 is important. The time tb1 is appropriately set or changed by observing the waveform of the Vce voltage of the transistor 117.

The switch circuit 124a is turned off tm1 time before the Vgs signal of the transistor 117 reaches Vt. The tm1 time is configured to be changeable by a control circuit board (controller) 111.

The switch circuit 124b is turned on ta2 hours before the switch circuit 124a is turned off. The on state of the switch circuit 124b is maintained until ta1 time after the switch circuit 124a is turned off. The ta2 time and ta1 time can be changed and set independently.
In particular, the setting of ta1 is important. The time of ta1 is appropriately set or changed by observing or measuring the waveform of the Vce voltage of the transistor 117.

When the switch circuit Ssb is turned on, the output terminal of the power supply circuit 121 is short-circuited to the ground (ground line), and the electric charge is discharged. As the charges are discharged, the terminal voltage of the power supply circuit 121 becomes 0 (V) (ground voltage). Further, the current Id output by the power supply circuit 121 is passed to the ground as a current Im. Therefore, current Id is not applied to transistor 117, and the collector voltage of transistor 117 does not rise.

The tb2 time is determined by observing or observing the time when the output voltage of the power supply circuit 121 becomes 0 (V) or near 0 (V), or the time when the output voltage of the power supply circuit 121 becomes lower than the collector voltage of the transistor 117. Measure and set.

At the time when the above voltage relationship reaches a predetermined value (after tb2), the switch circuit 124a is turned on and the current Id from the power supply circuit 121 is applied. However, at this time, since the switch circuit 124b is on, the current Id from the power supply circuit 121 flows to the ground (ground line) as a current Im via the switch circuit 124b. Therefore, constant current Id does not flow through transistor 117.
After a time tb1 has elapsed since the switch circuit 124a was turned on, the switch circuit 124b is turned off and the test current Id is supplied to the transistor 117.
The test current Id is supplied to the transistor 117 in synchronization with the switch circuit 124a, as shown in FIG.

By operating the switch circuits 124a and 124b as described above, the surge voltage Vs or rush current Is is not applied to the transistor 117. Alternatively, the surge voltage Vs or the rush current Is is suppressed, and a good test of the transistor 117 can be performed.

When the test current Id to the transistor 117 is stopped, the switch circuit 124b is turned on before the switch circuit 124a is turned off ta2. The constant current Id output from the power supply circuit 121 flows to the ground as a current Im via the switch circuit Ssb, and is not supplied to the transistor 117.

For time ta2, observe the time when the output voltage of the power supply circuit 121 becomes 0 (V) or near 0 (V), or the time when the output voltage of the power supply circuit 121 becomes lower than the collector voltage of the transistor 117. Set.

At the time when the above voltage relationship reaches a predetermined value (after ta2 has elapsed), the switch circuit 124a is turned off. After a period of time ta1 has elapsed since the switch circuit 124a was turned off, the switch circuit 124b is turned off.

By operating or controlling the switch circuits 124a and 124b as described above, the surge voltage Vs or rush current Is is not applied to the transistor 117. Alternatively, the surge voltage Vs or the rush current Is is suppressed, and a good test of the transistor 117 can be performed.

By supplying the constant current Id to the transistor 117, the temperature information Tj increases. By stopping the constant current Id to the transistor 117, the temperature information Tj decreases. Temperature information Tj fluctuates between T1 and T2. When the characteristics of the transistor 117 change due to the test, the temperature information Tj gradually increases.
In order to apply a constant value of current Id to the transistor 117, the power supply circuit 121 is operated and the current Id is applied to the transistor 117.

As illustrated in FIGS. 14, 25, 26, 31, 27, 28, etc., the resistance value of the variable resistance circuit 125 of the gate driver circuit 113 can also be set. By increasing the resistance value, the rising/falling waveform of the gate signal Vgs can be changed as shown by the dotted line or the dashed-dotted line in FIG. 31(a).

By changing or setting the gate signal Vgs, the current Id flowing through the transistor 117 can also be changed as indicated by a dotted line or a dashed-dotted line, as shown in FIG. 31(b).
By changing the rising waveform and falling waveform of the current Id, the surge voltage or rush current can be adjusted or suppressed.

As shown in FIG. 31C, the temperature information Tj changes from a solid line to a dotted line and from a dotted line to a dashed-dotted line as the characteristics of the transistor 117 change due to the test. The test is stopped when the temperature information Tj reaches the level of Tm. Alternatively, the test is stopped when the rate of change of the temperature information Tj reaches a predetermined value. Also, change the test conditions.

As shown in FIG. 32, when the switch circuit Ssa (switch circuit 124a) is in the off state, the St1 signal is set to H and the temperature information Tj is measured. The St1 signal is set to H level when the gate signal is Vt. During the tn2 period, the temperature information Tj is measured by setting the temperature to H level during the tc2 period. During the tn1 period, temperature information Tj is measured during the tc1 period.

The temperature information Tj measured during the period tc2 becomes the temperature information Tj at the time when the transistor 117 is cooled down. The temperature information Tj measured during the tc1 period becomes the temperature information Tj immediately after the current Id to the transistor 117 is stopped.
Stopping the test, changing conditions, changing control, etc. is determined based on the temperature information Tj measured during the tc2 period and the temperature information Tj measured during the tc1 period.

If the temperature information Tj measured during the tc1 period has a larger rate of change than the temperature information Tj measured during the tc2 period, the absolute value of the temperature information Tj measured during the tc1 period with the temperature information Tj measured during the tc2 period. If the difference in temperature is large, the test is controlled and changed in accordance with the measured value temperature information Tj.

In addition, if the temperature information Tj measured during the period tc2 is different from the standard value by a predetermined value, it is determined whether there is a problem with the connection state of the transistor 117 or the test equipment, and a decision is made to "not start the test". conduct.
Vi is measured multiple times during the tc2 or tc1 period, and temperature information Tj with respect to Vi is obtained.

The embodiment shown in FIG. 27 is a semiconductor device testing apparatus according to the second embodiment of the present invention. The transistor 117 in FIG. 27 is provided with a separate diode Ds (diode Dsa, diode Dsb) for temperature measurement. Note that the diode Ds is formed in the same process as the transistor 117.

In the embodiment shown in FIG. 27, the temperature information Tj is measured at the timing of the St2 signal shown in FIG. 30(d). When the switch circuit Ssa (switch circuit 124a) is in the off state, the St2 signal is set to H and the temperature information Tj is measured. During the tn2 period, the temperature information Tj is measured by setting the temperature to H level during the tc2 period. The temperature information Tj may be measured during the period tc1, during the period ton, or during the period tn1. The temperature information Tj measured during the tc2 period and the temperature information Tj measured during the tc1 period are averaged to obtain temperature information Tj.

Note that Vi is measured multiple times during the tc2 or tc1 period, and temperature information Tj with respect to Vi is obtained. The operations of other signals or switch circuits in FIG. 30 are the same as or similar to the embodiments described in FIG. 14 and the like.
In the embodiments described above, temperature information Tj is measured using a diode added to or formed in the transistor 117.
In the embodiment of FIG. 27, a diode Ds not connected to the transistor (independent) is formed in the transistor 117.

The diode Dsa is formed in a direction in which a constant current Ic flows. The diode Dsb is formed in a direction in which a constant current Ic' flows. Constant current circuit 118 (Pc) generates constant current Ic and constant current Ic'.

The diode Dsa and the diode Dsb are diodes for temperature measurement. The structures of the diode Dsa and the diode Dsb are similar or the same as the diode Di shown in FIG. 14 and the like.

The diode Di is connected to the terminals of the transistor 117 (terminal c, terminal e), whereas the diode Dsa and the diode Dsb are not connected to the terminal of the transistor 117, but are connected to independent terminals. The temperature information Tj of the diode Di is measured at the timing St1 in FIG. 30(c), whereas the temperature information Tj of the diode Dsa and Dsb is measured at the timing St2 of FIG. 30(d). have the same operation or configuration.

In the embodiment of FIG. 27, the diode Ds is separated from the path through which the constant current Id flows. Even when a current Id is flowing through the transistor 117, a constant current Ic can be caused to flow through the diode. Therefore, the time for measuring the temperature information Tj can be freely set. As illustrated in FIG. 30(d), the positions of tc1 and tc2 can be set.

However, in tc2, as shown in FIG. 30(d), the gate signal is placed or set in the period of Vt. The temperature information Tj measured during the period tc2 is used as a value before the transistor 117 operates. The period tc1 is preferably just before the constant current Id of the transistor 117 is stopped. Note that it may be done immediately after the constant current Id is stopped. It is preferable that the time immediately before and immediately after is within 1 msec.
St2 in FIG. 30(d) is a timing signal for causing current Ic (or current Ic') to flow through the diode Ds (Dsa, Dsb).

When St2 is at H level, current flows through the diode Ds (Dsa, Dsb) of the transistor 117. The operational amplifier circuit 116 acquires the voltage between the terminals of the diode Ds, and the temperature measurement circuit 115 converts the voltage between the terminals into temperature information Tj.

The temperature information Tj is sent to the control circuit board (controller) 111, and the control circuit board (controller) 111 performs or stops testing the transistor 117 or changes control according to the temperature information Tj.

When St2 is at H level, constant current circuit 118 causes constant current Ic to flow, and constant current Ic flows through diode Dsa. Further, the constant current circuit 118 flows a constant current Ic', and the constant current Ic' flows through the diode Dsb.

Constant current Ic and constant current Ic' are currents of the same magnitude. However, when the threshold voltages of the diode Dsa and the diode Dsb are different, or when the characteristics of the diode Dsa and the diode Dsb are different, it is preferable to make the constant current Ic and the constant current Ic' different in magnitude.

The operational amplifier circuit 116 acquires the voltage between the terminals of the diode Dsa or Dsb, and the temperature measurement circuit 115 converts the voltage between the terminals into temperature information Tj. The temperature information Tj is sent to the control circuit board (controller) 111, and the control circuit board (controller) 111 tests the transistor 117 based on the temperature information Tj.

Tj obtained by flowing a constant current Ic and temperature information Tj obtained by flowing a constant current Ic' are averaged or subjected to weighting processing to form one value of temperature information Tj. Using this temperature information Tj, the control circuit board (controller) 111 performs or stops testing the transistor 117, or changes control.
Other matters are the same as or similar to the matters or contents described in this specification and the drawings, so their explanation will be omitted.

It goes without saying that the present invention can be modified in various ways without departing from the spirit thereof. It goes without saying that the matters or contents described in this specification and the drawings can be combined with each other.

FIG. 28 is an explanatory diagram of a semiconductor device testing apparatus in a third embodiment of the present invention. The difference from FIG. 14 is that the diode-connected transistor 117s is placed in the path of the current Id flowing through the transistor 117m to be tested. Since the other parts are the same, the explanation will be omitted.

The transistor 117s is, for example, a transistor with the same specifications as the transistor 117m to be tested. The gate terminal g2 and emitter terminal e2 of the transistor 117s are connected, and the transistor 117s can be equivalently regarded as a diode. The gate terminal g2 and emitter terminal e2 of the transistor 117s are connected to the O terminal of the element terminal 226. The collector terminal c2 of the transistor 117s is connected to the P terminal of the element terminal 226.

The terminals (gate terminal g2, emitter terminal e2, collector terminal c2) of the transistor 117s are connected to a connector 202b, as shown in FIG. 24, and the connector 202b is connected to the sample connection circuit 203 by a signal wiring 222b. The terminals (gate terminal g2, emitter terminal e2, collector terminal c2) of the transistor 117s are connected within the sample connection circuit 203.

When the switch circuit 124b is turned on, a current Im flows to discharge the electric charge in the power supply circuit 121. Alternatively, the current Id output by the power supply circuit 121 is caused to flow to the ground via the switch circuit 124b.

When a rush current Is flows through the transistor 117m to be tested, the transistor 117m is destroyed by the generation of the rush current Is or the surge voltage Vs. In order to prevent the generation of inrush current Is or surge voltage Vs, on/off control and on/off order of switch circuits 124a and 124b are controlled.

When testing the transistor 117m by increasing the cycle tcycle, it is necessary to quickly turn on and off the switch circuits 124a and 124b. In this case, depending on the on/off timing of the switch circuit 124, an inrush current Is or a surge voltage Vs may occur.

If the voltage Vm at the collector terminal of the transistor 117 is higher than the voltage Vp at the output section of the power supply circuit, the current flows toward the ground as a current Im, and no or only a small amount flows through the transistor 117m.

In order to create the relationship Vm>Vp, in the embodiment shown in FIG. 28, a diode-connected transistor 117s is placed in the path of the current Id. When current flows through the transistor 117s, the voltage Vm is accumulated by the channel voltage of the transistor 117s. Therefore, voltage Vp becomes lower than voltage Vm, and no rush current is applied to transistor 117m. The transistor 117m will not be destroyed by the rush current Is or the surge voltage Vs.

FIG. 29 is an explanatory diagram of a semiconductor device testing apparatus according to a fourth embodiment of the present invention. In FIG. 29, a plurality of transistors 117 (transistors 117Q1 to 117Qn) to be tested are connected in parallel to the power supply circuit 121.

The fourth embodiment includes one switch circuit board 201a and n switch circuit boards 201b (switch circuit board 201b1 to switch circuit board 201bn). There are n transistors 117Q (transistors 117Q1 to 117Qn) to be tested simultaneously or sequentially.

The collector terminal of transistor Q1 is connected to fork plug 205e1, and the emitter terminal of transistor Q1 is connected to fork plug 205c1.

The collector terminal of transistor Q2 is connected to fork plug 205e2, and the emitter terminal of transistor Q2 is connected to fork plug 205c2.

The collector terminal of transistor Q3 is connected to fork plug 205e3, and the emitter terminal of transistor Q3 is connected to fork plug 205c3.

Similarly, the collector terminal of the transistor Qn is connected to the fork plug 205en, and the emitter terminal of the transistor Qn is connected to the fork plug 205cn.

The current Ic of the constant current circuit 118 is supplied to the diode Ds of the transistor 117Q1 by turning on the switch circuit Ssa1. The terminal voltage of the diode Ds is applied to the operational amplifier (buffer) 116, and is output from the operational amplifier circuit 116 as a Vi1 voltage.

The current Ic of the constant current circuit 118 is supplied to the diode Ds of the transistor 117Q2 by turning on the switch circuit Ssa2. The terminal voltage of the diode Ds is applied to the operational amplifier (buffer) 116, and is output from the operational amplifier circuit 116 as a Vi2 voltage.

Similarly, the current Ic of the constant current circuit 118 is supplied to the diode Ds of the transistor 117Qn by turning on the switch circuit Ssan. The terminal voltage of the diode Ds is applied to the operational amplifier (buffer) 116, and is output from the operational amplifier circuit 116 as the Vin voltage.
One of the voltages Vi1 to Vin is selected by the selector 127, outputted as Vi, and inputted to the temperature measurement circuit 115.

The temperature measurement circuit 115 obtains temperature information Tj and outputs it to the control circuit board 111. Note that in the embodiment of FIG. 29, there is one constant current circuit 118, but the present invention is not limited to this. A constant current circuit 118 may be arranged for each transistor 117Q. Further, the temperature measurement circuit 115 may be formed or placed in each transistor 117Q.
Voltage data Vi and temperature information Tj are sent to control circuit board 111 via wiring on mother board 207.

The element terminal 226 (P terminal) of the transistor 117Q1 is connected to the connection structure 218a1. The element terminal 226 (N terminal) of the transistor 117Q1 is connected to the connection structure 218b1.

The element terminal 226 (P terminal) of the transistor 117Q2 is connected to the connection structure 218a2. The element terminal 226 (N terminal) of the transistor 117Q2 is connected to the connection structure 218b2.

Similarly, the element terminal 226 (P terminal) of the transistor 117Qn is connected to the connection structure 218an. The element terminal 226 (N terminal) of the transistor 117Qn is connected to the connection structure 218bn. Note that n is a positive number of 1 or more.
Connection structure 218 is inserted through opening 216 provided in partition wall 217 . The connection structure 218 is inserted from the C2 chamber toward the C1 chamber.

The fork plug 205 is inserted into the B chamber from the C2 chamber side through an opening 216 formed in the partition wall 214. The fork plug 205 is connected to the conductor plate 204 of the switch circuit board 201 by being inserted. The switch circuit board 201 can be selected depending on the position of the opening 216 into which the fork plug 205 is inserted.

By changing the position of the switch circuit board 201 connected to the connector 213 of the mother board 207, the switch circuit board 201 to be selected by the fork plug 205 can be selected.

Two conductor plates 204 are arranged on the switch circuit board 201. Of the two conductor plates 204, the conductor plate 204 is arranged so that the conductor plate 204 on the side closer to the C2 chamber and the fork plug 205 are connected (in contact).

In the embodiment of the present invention, the fork plug 205 and the conductive plate 204 are brought into contact and electrically connected, but the present invention is not limited to this. Any device may be used as long as it can change between an electrically connected state and a non-connected state by mechanical operation. Further, any configuration may be used as long as the connected state can be stably maintained.

For example, instead of the fork plug 205, a rotary connector, rotary joint, high current connector, etc. may be used. Instead of the conductor plate 204, a rotary connector, a rotary joint, a large current connector, a cylindrical conductor bar, a square conductor bar, a comb-shaped conductor plate, etc. may be used instead.

FIG. 33 is an explanatory diagram of the semiconductor device testing method in the embodiment of the present invention, explaining the operation of FIG. 29. It is possible to conduct a semiconductor test by turning on the transistors 117Q (transistors 117Q1 to 117Qn) at the same time. In this case, it is necessary to flow a constant current Id through all of the transistors 117Q (transistors 117Q1 to 117Qn). Therefore, if the power supply circuit 121 has n transistors 117Q, it needs to be able to output a current of Id×n (n is a positive number of 1 or more). Therefore, a large capacity power supply circuit 121 is required.

If the test is performed by sequentially turning on the transistors 117Q and applying the constant current Id to the transistors 117Q, the constant current output by the power supply circuit 121 may be Id. FIG. 33 shows an example of a test method for a semiconductor device testing apparatus in which a test is performed by sequentially turning on the transistors 117Q. The semiconductor element changes depending on the number of times the constant current Id is turned on and off.

Therefore, by conducting a test by sequentially turning on semiconductor elements (transistor 117Q, etc.) as shown in FIG. 33, the test can be carried out efficiently, and the maximum output current capacity of the power supply circuit 121 can be reduced.

In FIG. 33, the number of transistors 117Q to be turned on will be explained as one, but the number is not limited to this. For example, a plurality of transistors 117Q may be turned on simultaneously. In this case, the maximum value of the constant current output by the power supply circuit 121 is equal to the number of transistors 117Q to be turned on×Id.

Further, in the embodiment of the present invention, one power supply circuit 121 is illustrated, but the present invention is not limited to this. For the power supply circuit 121, a power supply circuit 121b may be separately installed. Furthermore, two or more power supply circuits 121 may be installed. By installing a plurality of power supply circuits 121, the current Id flowing through the transistor 117 can have various waveforms.
The above matters also apply to the embodiments of the present invention.

As shown in FIG. 33(a), when the switch circuit St1 (151s1) to the switch circuit Stn (151sn) are turned on, constant currents Id1 to Idn flow through the transistor 117. For example, the application time of the constant current Id is ton, and the constant current Id1 and the constant current Id2 are sequentially applied to the transistor 117 at an interval of time tcycle. By turning on the transistor 117, the channel voltage of the transistor 117Q sequentially changes (FIG. 33(c)).

Therefore, for example, constant current Id1 and constant current Id2 do not overlap in time. Therefore, the output capacitance of the power supply circuit 121 may be the output capacitance required for testing one transistor 117Q.

The constant currents Id (constant currents Id1 to constant currents Idn) are controlled so that they do not overlap. Furthermore, it is preferable that an interval of 1 μsec or more be provided between each of the constant currents Id (constant currents Id1 to constant currents Idn). Note that the driving method and control method described with reference to FIG. 30 are performed for each transistor 117Q.

The constant current Ic supplied to each transistor 117Q is supplied to the diode Ds of each transistor 117Q by sequentially turning on the switch circuits Ssa (Ssa1 to Ssan).

The voltage Vi (Vi1 to Vin) corresponding to the terminal voltage of the diode Ds is selected by the selector 127 in synchronization with the switch circuit Ssa (Ssa1 to Ssan). For example, when current Ic is supplied to transistor 117Q1, selector 127 selects the terminal voltage of diode Ds of transistor 117Q1. When the current Ic is supplied to the transistor 117Q3, the selector 127 selects the terminal voltage of the diode Ds of the transistor 117Q3. The selected voltage Vi is supplied to temperature measurement circuit 115.
The other configurations and operations are the same as those described in other embodiments, so their explanations will be omitted.
In the embodiments of the present invention, the transistor 117 has been described using an IGBT as an example, but the transistor 117 is not limited to this.

For example, N-channel JFET (Figure 40(a)), P-channel JFET (Figure 40(b)), N-channel MOSFET (Figure 40(c)), P-channel MOSFET (Figure 40(d)), It goes without saying that an N-channel bipolar FET (FIG. 40(e)) or a P-channel bipolar FET (FIG. 40(f)) may be used.

Further, the present invention is not limited to a three-terminal device, and may be a two-terminal element such as a diode shown in FIG. 40(g). A two-terminal device does not require a gate signal Vgs. It goes without saying that the semiconductor device testing apparatus and semiconductor device testing method of the present invention can be applied by testing by flowing a constant current Id through the power supply circuit 121.

Furthermore, the semiconductor element testing apparatus of the present invention is not limited to transistors and diodes, and may also include other semiconductor elements such as thyristors and triacs, varistors, diacs, or modules in which transistors, diode resistors, etc. are mixed or integrated. Needless to say, the method for testing semiconductor devices can be applied.

In the present invention, an N-channel transistor will be described as an example of the semiconductor element 117, but the present invention is not limited to this. For example, it goes without saying that the present invention is applicable to P-channel transistors as well. In addition to the semiconductor elements shown in FIGS. 40(a) to 40(i), electrical components such as resistors (FIG. 40(i)), capacitors, coils, relays, and crystal oscillators (FIG. 40(k)) are also available. Needless to say, it can also be handled.

Although the present invention has been specifically described above based on the embodiments, it goes without saying that the present invention is not limited thereto and can be modified in various ways without departing from the gist thereof.
It goes without saying that the matters or contents described in this specification and the drawings can be combined with each other.

For example, the switch circuit 124a and the switch circuit 124b shown in FIG. 26 can be applied to other embodiments. For example, it goes without saying that the configurations and operations shown in FIGS. 29 and 33 can be applied to other embodiments such as those shown in FIGS. 27 and 28.

The present invention enables easy connection changes depending on the test content of semiconductor devices such as transistors and the number of simultaneous tests of semiconductor devices, and the contact resistance of the connection portion of the semiconductor device is small, so even if the test current is large, the connection can be changed easily. Accordingly, it is possible to provide a semiconductor device testing device and a semiconductor testing method that can perform tests in a variety of ways.

111 Control circuit board (controller)
112 Gate signal control circuit 113 Gate driver circuit 115 Temperature measurement circuit 116 Operational amplifier (buffer amplifier)
117 Power transistor 118 Constant current circuit 121 Constant current circuit 122 Switch circuit 124 Switch circuit 125 Variable resistance circuit 127 Selector 131 Control rack 132 Power supply 133 Control circuit 134 Heating/cooling plate 135 Circulating water pipe 136 Chiller 201 Switch circuit board 202 Connector 203 Sample Connection circuit 204 Conductor plate 205 Fork plug 206 Connection pin 207 Motherboard 208 Connector 209 Device control circuit board 210 Housing 211 Connection wiring 212 Power supply wiring 213 Connector 214 Partition 215 Partition 216 Opening 217 Partition 218 Connection structure 219 Connection bolt 220 Contact Part 221 Fixing screw 222 Signal wiring 223 Heat pipe 224 Fixing screw 225 Connection receiving part 226 Element terminal 227 Cooling fan 228 Radiation fin 231 Heat pipe fitting 232 Connection pressure part 233 Connection holding part 234 Recess 235 Signal wiring 236 Spring (pressure fitting)
237 Position fixing screw 238 Screw hole 239 Spring hole 240 Positioning screw hole 251 Convex portion 252 Groove 301 Test circuit module 302 Voltage selection circuit 311 Pressing tool 312 Insulating plate 313 Pressing tool mounting plate 315 Insulating section 316 Thermocouple

Claims (10)

An electrical element testing device for testing an electrical element having a first terminal, a second terminal , and a gate terminal ,
a heating and cooling plate for arranging and fixing the electric element;
a first connection structure that pinches and connects the first terminal;
a second connection structure that pinches and connects the second terminal;
a gate driver circuit that applies a voltage signal consisting of an on voltage and an off voltage to the gate terminal;
a voltage measurement circuit that measures the voltage between the first terminal and the second terminal;
a first heat pipe attached to the first connection structure;
a second heat pipe attached to the second connection structure;
a power supply device having a third terminal and a fourth terminal and supplying a test current or a test voltage to the electric element;
a plurality of switch circuit boards on which switch circuits are mounted or formed;
a first conductor plate attached to the switch circuit board;
a second conductor plate attached to the switch circuit board;
comprising a constant current circuit that applies a constant current between the first terminal and the second terminal,
The first connection structure and a first conductor plate of a switch circuit board selected from the plurality of switch circuit boards are connected,
the third terminal and a second conductor plate of the selected switch circuit board are connected;
the second connection structure and the fourth terminal are connected,
The switch circuit has a first operation of short-circuiting between the first conductor plate and the second conductor plate, and a second operation of short-circuiting between the first conductor plate and the second conductor plate. perform the action,
When the switch circuit is in the second operation, the constant current circuit supplies the constant current between the first terminal and the second terminal, and the voltage measurement circuit supplies the constant current between the first terminal and the second terminal. An electrical element testing device characterized by measuring voltage changes between terminals of. An electrical element testing device for testing an electrical element having a first terminal, a second terminal, and a gate terminal,
a heating and cooling plate that clamps and fixes the electric element above and below the electric element;
a first connection structure that pinches and connects the first terminal;
a second connection structure that pinches and connects the second terminal;
a first heat pipe attached to the first connection structure;
a second heat pipe attached to the second connection structure;
a first heat dissipation fin arranged on the first connection structure;
a second heat dissipation fin arranged on the second connection structure;
a gate driver circuit that applies an on voltage or an off voltage to the gate terminal;
a power supply device having a third terminal and a fourth terminal and supplying a test current or a test voltage to the electric element;
a plurality of switch circuit boards on which switch circuits are mounted or formed;
a first conductor plate attached to the switch circuit board;
a second conductor plate attached to the switch circuit board;
a constant current circuit that applies a constant current between the first terminal and the second terminal;
comprising a voltage measurement circuit that measures the voltage between the first terminal and the second terminal,
The first connection structure and a first conductor plate of a switch circuit board selected from the plurality of switch circuit boards are connected,
the third terminal and a second conductor plate of the selected switch circuit board are connected;
the second connection structure and the fourth terminal are connected,
The switch circuit has a first operation of short-circuiting between the first conductor plate and the second conductor plate, and a second operation of short-circuiting between the first conductor plate and the second conductor plate. perform the action,
When the switch circuit is in the second operation, the constant current circuit supplies the constant current between the first terminal and the second terminal, and the voltage measurement circuit supplies the constant current between the first terminal and the second terminal. An electrical element testing device characterized by measuring voltage changes between terminals of. An electrical element testing apparatus for testing an electrical element having a first terminal, a second terminal, a gate terminal, and a diode connected to the first terminal and the second terminal,
a heating and cooling plate for arranging and fixing the electric element;
a first connection structure that pinches and connects the first terminal;
a second connection structure that pinches and connects the second terminal;
a gate driver circuit that applies a voltage signal consisting of an on voltage and an off voltage to the gate terminal;
a constant current circuit that applies a constant current to the diode;
a first heat pipe attached to the first connection structure;
a second heat pipe attached to the second connection structure;
a power supply device having a third terminal and a fourth terminal and supplying a test current or a test voltage to the electric element;
a plurality of switch circuit boards on which switch circuits are mounted or formed;
a first conductor plate attached to the switch circuit board;
a second conductor plate attached to the switch circuit board;
comprising a voltage measurement circuit that measures the voltage between the first terminal and the second terminal,
The first connection structure and a first conductor plate of a switch circuit board selected from the plurality of switch circuit boards are connected,
the third terminal and a second conductor plate of the selected switch circuit board are connected;
the second connection structure and the fourth terminal are connected,
The switch circuit has a first operation of short-circuiting between the first conductor plate and the second conductor plate, and a second operation of short-circuiting between the first conductor plate and the second conductor plate. perform the action,
When the switch circuit is in the second operation, the constant current circuit supplies the constant current to the diode, and the voltage measurement circuit measures a voltage change between terminals of the diode. Test equipment. An electrical element testing device for testing an electrical element having a first terminal, a second terminal , and a gate terminal ,
a heating and cooling plate for arranging and fixing the electric element;
a first connection structure that pinches and connects the first terminal;
a second connection structure that pinches and connects the second terminal;
a gate driver circuit that applies a voltage signal consisting of an on voltage and an off voltage to the gate terminal;
a first heat pipe attached to the first connection structure;
a second heat pipe attached to the second connection structure;
a power supply device having a third terminal and a fourth terminal and supplying a test current or a test voltage to the electric element;
a plurality of first switch circuit boards on which first switch circuits are mounted or formed;
a second switch circuit board on which a second switch circuit is mounted or formed;
a first conductor plate attached to the first switch circuit board;
a second conductor plate attached to the first switch circuit board;
a third conductor plate attached to the second switch circuit board;
a fourth conductor plate attached to the second switch circuit board;
a constant current circuit that applies a constant current between the first terminal and the second terminal;
comprising a voltage measurement circuit that measures the voltage between the first terminal and the second terminal,
The first connection structure and a first conductor plate of a first switch circuit board selected from the plurality of first switch circuit boards are connected,
The third terminal is connected to a second conductor plate of a first switch circuit board selected from the plurality of first switch circuit boards,
the second connection structure and the fourth terminal are connected,
the third terminal and the third conductor plate of the second switch circuit board are connected,
the fourth terminal and the fourth conductor plate of the second switch circuit board are connected,
The first switch circuit performs a first operation of short-circuiting between the first conductor plate and the second conductor plate, and opening between the first conductor plate and the second conductor plate. perform the second action,
The second switch circuit performs a first operation of short-circuiting between the third conductor plate and the fourth conductor plate, and opening between the third conductor plate and the fourth conductor plate. perform the second action,
The second switch circuit short-circuits the first terminal and the second terminal,
When the first switch circuit of the first switch circuit board is in the second operation, the constant current circuit supplies the constant current between the first terminal and the second terminal, and measures the voltage. An electrical element testing apparatus, wherein the circuit measures a voltage change between the first terminal and the second terminal. An electrical element testing device for testing an electrical element having a first terminal, a second terminal , and a gate terminal ,
a heating and cooling plate for arranging and fixing the electric element;
a first connection structure that pinches and connects the first terminal;
a second connection structure that pinches and connects the second terminal ;
a gate driver circuit that applies a voltage signal consisting of an on voltage and an off voltage to the gate terminal;
a first heat pipe attached to the first connection structure;
a second heat pipe attached to the second connection structure;
a power supply device having a third terminal and a fourth terminal and supplying a test current or a test voltage to the electric element;
a plurality of switch circuit boards on which switch circuits are mounted or formed;
a first conductor plate attached to the switch circuit board;
a second conductor plate attached to the switch circuit board;
a connecting member;
a constant current circuit that applies a constant current between the first terminal and the second terminal;
comprising a voltage measurement circuit that measures the voltage between the first terminal and the second terminal,
the first connection structure and the connection member are connected,
The connecting member and a first conductor plate of a switch circuit board selected from the plurality of switch circuit boards are connected,
the third terminal and the second conductor plate of the selected switch circuit board are connected;
the second connection structure and the fourth terminal are connected,
The electric element and the heating/cooling plate are arranged in a first chamber,
The switch circuit board is arranged in a second chamber below the first chamber,
an opening in the partition wall between the first chamber and the second chamber;
The connection member is inserted into the opening, and the tip of the connection member is fitted with the first conductor plate of the selected switch circuit board, so that the connection member and the first conductor plate of the selected switch circuit board are connected to each other. 1 conductor plate is connected,
The switch circuit has a first operation of short-circuiting between the first conductor plate and the second conductor plate, and a second operation of short-circuiting between the first conductor plate and the second conductor plate. perform the action,
When the switch circuit of the switch circuit board is in the second operation, the constant current circuit supplies the constant current between the first terminal and the second terminal, and the voltage measurement circuit supplies the constant current between the first terminal and the second terminal. An electric device testing device characterized by measuring a voltage change between a terminal and the second terminal. recesses are formed in the first connection structure and the second connection structure,
the first heat pipe is arranged in the recess of the first connection structure,
the second heat pipe is arranged in the recess of the second connection structure,
The coefficient of linear expansion of the material constituting the first connection structure and the second connection structure is smaller than the coefficient of linear expansion of the material constituting the first heat pipe and the second heat pipe. The electric device testing apparatus according to claim 3, 4, or 5, characterized in that: The first connection structure and the second connection structure have a connection receiving part and a connection holding part,
unevenness is formed on either the connection receiving part or the connection holding part,
Claim 1, claim 2, or claim 2, wherein a first terminal of the electrical element or a second terminal of the electrical element is held between the connection receiving part and the connection holding part. 3. The electric device testing device according to claim 3 or claim 4 or claim 5. The electric element testing apparatus according to claim 1, wherein the electric element is arranged in a first chamber, and dry air is introduced into the first chamber. . further comprising a resistor circuit disposed between the gate terminal and the gate driver circuit,
By adjusting the resistance value of the resistance circuit,
3. The electrical device testing apparatus according to claim 2, wherein a slope of a rising waveform and a slope of a falling waveform of the on-voltage or off-voltage can be set. further comprising a motherboard;
6. The electrical element testing apparatus according to claim 1, wherein the plurality of switch circuit boards are connected to the mother board via a connector.

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