CN217007495U

CN217007495U - Burn-in equipment

Info

Publication number: CN217007495U
Application number: CN202121134114.7U
Authority: CN
Inventors: 甘明达
Original assignee: Minmax Technology Co Ltd
Current assignee: Minmax Technology Co Ltd
Priority date: 2021-05-25
Filing date: 2021-05-25
Publication date: 2022-07-19
Anticipated expiration: 2031-05-25

Abstract

The utility model relates to a burn-in device, which comprises a cabinet, a plurality of connecting devices and a burn-in test system, wherein the cabinet comprises a cabinet body and a plurality of carrier plates, the carrier plates are arranged in an accommodating space of the cabinet body at intervals, the connecting devices are arranged in the cabinet, each connecting device comprises a circuit substrate and at least one adapter, the circuit substrate is provided with a plurality of load areas, the positions of the load areas are separated from each other, the circuit substrate is provided with a plurality of contacts in each load area, the adapter is detachably arranged on the circuit substrate and electrically connected with the contacts, each adapter is provided with at least one connector of an element to be tested, each carrier plate of the cabinet is provided with at least one connecting device of the connecting devices, and the burn-in test system is arranged in the cabinet and electrically connected with the connecting devices.

Description

Burn-in equipment

Technical Field

The present invention relates to a burn-in apparatus, and more particularly, to a burn-in test apparatus for use in an electronic device executing a burn-in program.

Background

Before the existing electronic device leaves the factory, in order to ensure the function accuracy and reliability of the electronic device, a burn-in program (burn-in) is performed, and the burn-in program is used to simulate the load status of the electronic device for testing.

Referring to fig. 9, in the conventional burn-in method, an electronic device to be tested (hereinafter referred to as a device under test 60) is connected to a power supply 50, a load device 51 and a measurement device 52, a control device 53 controls the magnitude of the test power output from the power supply 50 to the device under test 60, the load device 51 may be an electronic load (electronic load) or a custom cement resistor, the measurement device 52 may be electrically connected to the output terminal of the device under test 60 to measure the output voltage and/or current thereof, the control device 53 receives the measurement data from the measurement device 52, and the control device 52 may store the measurement data in a storage device (e.g., a hard disk) and present the measurement data to a user through a display.

However, since the types of the devices 60 to be tested are different, the loading capacities of different types of the devices 60 to be tested are different, and thus the impedance of the loading device 51 must be adjusted, replaced or customized according to the types of the devices 60 to be tested, which makes the conventional burn-in process difficult to simplify.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide burn-in equipment, aiming at overcoming the defect that the known burn-in process is difficult to simplify.

In order to achieve the above object, the present invention provides a burn-in apparatus comprising:

the equipment cabinet comprises a cabinet body and a plurality of support plates, wherein the cabinet body is provided with a containing space, and the plurality of support plates are arranged in the containing space of the cabinet body at intervals;

a plurality of connecting devices installed in the cabinet, each of the connecting devices including:

the circuit substrate is provided with a plurality of load areas, the positions of the load areas are separated from each other, and the circuit substrate is provided with a plurality of contacts in each load area; and

at least one adapter which is detachably arranged on the circuit substrate and electrically connected with the plurality of contacts, and each adapter is provided with at least one element connector to be tested;

each carrier plate of the cabinet is provided with at least one connecting device in the plurality of connecting devices; and

and the burn-in test system is arranged in the cabinet and is electrically connected with the plurality of connecting devices.

According to the burn-in equipment, the front side of the cabinet body is provided with the front side plate, and the plurality of carrier plates are arranged in the accommodating space at intervals up and down.

In the burn-in apparatus, two sides of each carrier plate are respectively connected to the cabinet body by a drawer slide rail.

In the burn-in apparatus, the at least one dut connector of each adapter is a plurality of dut connectors.

In the burn-in apparatus, the at least one dut connector of each adapter is a single dut connector.

In the aforementioned burn-in apparatus, the at least one adapter is a plurality of adapters, and the dut connector of each adapter is electrically connected to the contacts of at least two of the load areas of the circuit substrate.

In the burn-in apparatus, the at least one adapter is a single adapter, and the dut connector thereof is electrically connected to the contacts of the plurality of load areas of the circuit substrate.

The utility model has the beneficial effects that: the burn-in equipment only needs to replace the corresponding adapter for the elements to be tested with different models, and the burn-in equipment comprises a burn-in test system arranged in the cabinet and a circuit substrate which are of a common structure, so that the corresponding adapter for the elements to be tested with different models only needs to be replaced, and the adapter has small volume and light weight, so that an operator can take and place the adapter more simply and conveniently in a labor-saving way, and the burn-in process is simplified.

In addition, the burn-in equipment also has the characteristic of fully utilizing the height space, the burn-in equipment utilizes the accommodating space in the cabinet to arrange a plurality of carrier plates which are arranged at intervals, the carrier plates are used for providing a universal circuit substrate arrangement and providing a switching seat arrangement matched with the element to be tested, and in the using process, the element to be tested can be concentrated above the carrier plates which are arranged in layers and electrically connected with the switching seat on the circuit substrate, so that the burn-in equipment has the characteristic of fully utilizing the height space.

The utility model is described in detail below with reference to the drawings and specific examples, but the utility model is not limited thereto.

Drawings

FIG. 1: a front plan view schematic of an embodiment of the burn-in apparatus of the present invention.

FIG. 2: a partially enlarged schematic view of an embodiment of the burn-in apparatus of the present invention.

FIG. 3: in the present invention, a schematic top plan view of a circuit board is provided.

FIG. 4: in the present invention, a block diagram of an embodiment of a burn-in test system is shown.

FIG. 5 is a schematic view of: in the present invention, a schematic top plan view (i) of a combination structure of a circuit substrate and an interposer.

FIG. 6: in the present invention, the top plan view of the combination structure of the circuit substrate and the adapter is schematically shown in the second embodiment.

FIG. 7: in the present invention, a top plan view schematically shows a combination structure of the circuit substrate and the interposer (iii).

FIG. 8: in the present invention, a top plan view schematically (iv) of the connection structure of the circuit board and the interposer.

FIG. 9: a block diagram of a burn-in test for a device under test is known.

The reference numbers illustrate:

10 cabinet and 11 cabinet body

110 holding space 12 carrier plate

13 front side plate 14 drawer slide rail

20 connecting device 21 circuit board

210 load region 211 test power contact

212 load contact 213 jack

22 adapter 220 connector for dut

221 terminal block 30 device under test

31 pin 41 control device

42 human-machine interface device 43 power supply

44 measuring device 45 load device

46 storage device 50 power supply

51 load device 52 measuring device

53 control device 60 device under test

Detailed Description

The structural and operational principles of the present invention are described in detail below with reference to the accompanying drawings:

the embodiment of the burn-in apparatus of the present invention includes a rack, a plurality of connection devices, and a burn-in test system, where each of the connection devices is used to connect a device under test, and the burn-in test system performs a burn-in test on the device under test, where the device under test may be an Integrated Circuit (IC), such as an IC product of a dc/dc power converter or an ac/dc power converter.

As shown in fig. 1 and fig. 2, the cabinet 10 includes a cabinet 11 and a plurality of carrier plates 12, the cabinet 11 has one or more accommodating spaces 110 therein, and the plurality of carrier plates 12 are disposed in the accommodating spaces 110 of the cabinet 11 at intervals. In the embodiment shown in fig. 1 and fig. 2, it is disclosed that the cabinet 11 has a receiving space 110 with a forward opening, and the front side of the cabinet 11 has a front side plate 13 at the side of the opening, the plurality of carrier plates 12 are arranged at intervals up and down in the receiving space, and two sides of each carrier plate 12 are respectively connected to a drawer slide 14 to connect with the side wall of the cabinet 11, so that the carrier plates 12 can be operated to be pulled out from the receiving space 110 of the cabinet 11 forward and pushed into the receiving space 110 by the drawer slide 14 at two sides.

As shown in fig. 1 and 2, the plurality of connecting devices 20 are installed in the cabinet 10, and each carrier board 12 of the cabinet 10 is provided with at least one connecting device 10 of the plurality of connecting devices 20, and in the embodiment shown in fig. 1 and 2, two connecting devices 20 may be provided on each carrier board 12. Each of the connecting devices 20 includes a circuit substrate 21 and at least one adapter 22, the circuit substrate 21 and the at least one adapter 22 can be Printed Circuit Boards (PCBs), so that the circuit substrate 21 and the at least one adapter 22 have electronic circuit layouts (layout), and the at least one adapter 22 is used for connecting devices 30 to be tested. Referring to fig. 3, the top surface of the circuit substrate 21 has a plurality of loading areas 210, the loading areas 210 are separated from each other, the circuit substrate 21 has a plurality of contacts in each loading area 210, and the contacts include a plurality of testing power contacts 211 and a plurality of loading contacts 212, which are electrically connected to the electronic circuit layout of the circuit substrate 21. In the embodiment shown in fig. 3, the circuit substrate 21 has eight load regions 210 arranged in a matrix. The at least one adapter 22 is detachably disposed on the circuit substrate 21 and electrically connected to the plurality of contacts, each adapter 22 has at least one device connector 220 to be tested, which is electrically connected to the electronic circuit layout of the adapter 22, each device connector 220 to be tested can be a plurality of terminal posts or conductive elastic clips, wherein each terminal post is a conductive hollow cylinder, each terminal post or conductive elastic clip is erected on the top surface of the adapter 22, and the positions of the terminal posts or conductive elastic clips correspond to the positions of pins 31 (pins) of the device 30 to be tested, so that one device 30 to be tested can be plugged into or pulled out of a group of device connectors 220 to be tested.

The adapter 22 and the circuit substrate 21 can be combined by pins (pins) and terminal blocks, for example, as shown in fig. 2, the bottom surface of the adapter 22 can be provided with terminal blocks 221 electrically connected to the dut connector 220 through the electronic circuit layout thereof, the top surface of each load region 210 of the circuit substrate 21 can be provided with pin sockets 213 electrically connected to the test power source contacts 211 and the plurality of load contacts 212 through the electronic circuit layout thereof, the terminal blocks 221 on the adapter 22 can be detachably connected to the pin sockets 213 on the circuit substrate 21, i.e., the pins of the pin sockets 213 can be inserted into and connected to the insertion holes of the terminal blocks 221, so that the electronic circuit layout of the adapter 22 and the electronic circuit layout of the circuit substrate 21 form an electrical connection. Therefore, with the above connection structure, when the adapter 22 is disposed on the circuit substrate 21, the dut connector 220 of the adapter 22 can electrically connect the test power contact 211 and the load contact 212 of the load area 210 of the circuit substrate 21; when the dut 30 is disposed on the dut connector 220 of the adapter 22, the dut 30 can be electrically connected to the test power contacts 211 and the load contacts 212 of the load area 210 of the circuit substrate 21 through the adapter 22.

Referring to fig. 4, the burn-in test system may include a control device 41, a human-machine interface device 42 electrically connected to the control device 41, a plurality of power supplies 43, a plurality of measuring devices 44, a plurality of load devices 45, and a storage device 46, where fig. 4 illustrates only one power supply 43, one measuring device 44, and one load device 45, and one connecting device 20 may be correspondingly connected to one power supply 43, one measuring device 44, and one load device 45. The power supply 43, the measuring device 44 and the load device 45 can be electrically connected to the electronic circuit layout of the circuit substrate 21 of the connecting device 20 to form an electrical connection with the device 30 to be tested, the control device 41 can control the magnitude of the test power outputted from the power supply 43 to each device to be tested, the load device 45 can be an electronic load (electronic load), the measuring device 44 can be a digital electric meter to measure the output voltage and/or current of the device 30 to be tested, the control device 41 receives the measurement data from the measuring device 44, the control device 41 can store the measurement data in a storage device 46 (e.g., a hard disk), and can present the measurement data to a user for viewing through a display of the hmi device 42. As shown in fig. 1, the human-machine interface device 42 may be mounted on the front side plate 13 of the cabinet 11 for an operator to view and operate, for example, the human-machine interface device 42 may be a touch display panel.

The connecting device 20 of the present invention can include several ways for each type of dut 30, and the electronic circuit layout of the circuit substrate 21 and the adapter 22 allows the contacts of the plurality of load regions 210 to be connected in parallel, and allows the plurality of dut connectors 220 to be connected in parallel, so that the plurality of load regions 210 and the plurality of dut connectors 220 can distribute or evenly distribute the load of the load device 45, as illustrated below.

1. In one mode

Referring to fig. 2 and fig. 5, the at least one adapter 22 is a plurality of adapters 22, and the number of the plurality of adapters 22 is the same as the number of the plurality of loading areas 210 of the circuit substrate 21, for example, the number of the plurality of adapters 22 may be eight, and the number of the plurality of loading areas 210 of the circuit substrate 21 is also eight, so as to form a one-to-one corresponding connection, that is, one adapter 22 is disposed in one loading area 210. As mentioned above, each adapter 22 may be provided with one or more connectors 220 for components to be tested, when each adapter 22 is provided with a plurality of connectors 220 for components to be tested, please refer to fig. 2 and 5 by taking an example that each adapter 22 is provided with two sets of connectors 220 for components to be tested, which are respectively provided for components to be tested 30, each component to be tested 30 forms a signal connection with the power supply 43, the load device 45 and the measurement device 44 through the electronic circuit layout of the adapter 22 and the circuit substrate 21, so that each component to be tested 30 can be tested, therefore, in the embodiment shown in fig. 5, eight adapters 22 are provided on the circuit substrate 21, each adapter 22 is provided with two components to be tested 30, so that the connection device 20 is provided with sixteen components to be tested 30 in total. When the load of the load device 45 is 600 watts (W), each dut 30 is equivalent to a load amount allocated to 37.5 watts (W), which is the upper power limit of the load amount simulated by the load device 45. As another example, referring to fig. 6, when each adapter 22 is provided with only a single dut 30 and the load of the load device 45 is 600 watts (W), each dut 30 is equivalent to a load amount allocated to 75 watts (W). Therefore, each adapter 22 can be provided with a different number of dut connectors 220 for connecting the dut 30 according to the requirement, and the load capacity of the dut 30 can be analogized from the foregoing example.

2. Mode two

The at least one adapter 22 is a plurality of adapters 22, the number of the plurality of adapters 22 is less than the number of the plurality of loading areas 210 of the circuit substrate 21, the dut connector 220 of each adapter 22 is electrically connected to the contacts of at least two loading areas 210 of the circuit substrate 21, that is, the dut connector 220 of each adapter 22 is electrically connected to the test power contacts 211 and the loading contacts 212 of a part of the loading areas 210 of the circuit substrate 21, that is, one adapter 22 can be correspondingly disposed in a plurality of loading areas 210, and thus, a one-to-many arrangement structure is provided. Referring to fig. 7 as an example, each adapter 22 is disposed in two load areas 210, a plurality of terminal blocks 221 are disposed on a bottom surface of each adapter 22, positions of the terminal blocks 221 correspond to positions of the plug sockets 213 of the two load areas 210 so as to be plugged in the plug sockets, each adapter 22 may be disposed with one or more dut connectors 220, and fig. 7 illustrates only one dut connector 220 for disposing one dut 30. In a case where the connection device 20 shown in fig. 7 is provided with a total of four dut 30, and the load of the load device 45 is 600 watts (W), each dut 30 is equivalent to a load amount allocated to 150 watts (W). Therefore, each adapter 22 can be provided with a different number of dut connectors 220 for connecting the dut 30 according to the requirement, and the load capacity of the dut 30 can be analogized from the foregoing example.

3. Mode III

The at least one adapter 22 is a single adapter 22, the dut connector 220 of the adapter 22 is electrically connected to the contacts of all the loading areas 210 of the circuit substrate 21, that is, the bottom surface of the adapter 22 is provided with a plurality of terminal blocks 221, and the positions of the terminal blocks 221 correspond to the positions of the socket 213 of the loading areas 210 so as to be able to be plugged correspondingly, thereby forming a one-to-many arrangement structure. Referring to fig. 8 as an example, the adapter 22 may be provided with a single dut connector 220 for installing one dut 30, and when the load of the load device 45 is 600 watts (W), the dut 30 is equivalent to a load amount distributed to 600 watts (W). Therefore, each adapter 22 can be provided with a different number of dut connectors 220 for connecting the dut 30 according to the requirement, and the load capacity of the dut 30 can be analogized from the foregoing example.

It should be noted that the circuit architecture described above is only an example, and in practical applications, the electronic circuit layout on each adapter 22 can be designed in a versatile and flexible manner according to the test requirements and the attributes of each type of device under test 30. In addition, the adapter 22 is provided with a corresponding number and a corresponding position of terminal blocks 221 on the size and the bottom surface thereof, so as to be capable of being correspondingly inserted into the socket 213 of the plurality of load areas 210.

In summary, in the present invention, only the corresponding adapter 22 needs to be installed and replaced for the devices 30 to be tested of different models, and the burn-in apparatus of the present invention includes the burn-in test system installed in the cabinet 10 and the circuit board 21 with a common structure, only the corresponding adapter 22 needs to be replaced for the devices 30 to be tested of different models, and the adapter 22 has a small volume and a light weight, so that an operator can easily and conveniently take and place the adapter 22 with less effort, thereby simplifying the burn-in process. The burn-in apparatus of the present invention further enables the cabinet to have a containing space 110 with a forward opening, the front side of the cabinet 11 has a front side plate 13, and the plurality of carrier plates 12 are arranged in the containing space 110 at intervals up and down, so that the cabinet 11 can provide a plurality of sets of devices 30 to be tested to perform a burn-in process by making full use of the space. Moreover, the present invention can further make both sides of each carrier plate 12 in the cabinet 11 respectively combine with the drawer slide 14 to connect with the cabinet 11, so that the carrier plates 12 can be moved out of the accommodating space 110 of the cabinet 11 and sent into the accommodating space 110, thereby facilitating the disassembling and assembling operation of the device 30 to be tested on the adapter 22 on the circuit substrate 21 in the cabinet 11.

The present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof, and it should be understood that various changes and modifications can be effected therein by one skilled in the art without departing from the spirit and scope of the utility model as defined in the appended claims.

Claims

1. A burn-in apparatus, comprising:

the equipment cabinet comprises a cabinet body and a plurality of support plates, wherein the cabinet body is provided with an accommodating space, and the plurality of support plates are arranged in the accommodating space of the cabinet body at intervals;

each carrier plate of the cabinet is provided with at least one connecting device in the plurality of connecting devices; and the burn-in test system is arranged in the cabinet and electrically connected with the plurality of connecting devices.

2. The burning device as claimed in claim 1, wherein the cabinet has a front side plate at the front side thereof, and the plurality of carrier plates are arranged in the accommodating space at intervals up and down.

3. The burning device as claimed in claim 1 or 2, wherein two sides of each carrier plate are respectively connected to the cabinet by a drawer slide.

4. The burn-in apparatus of claim 1 wherein said at least one dut connector of each adapter is a plurality of dut connectors.

5. The burn-in apparatus of claim 1 wherein said at least one dut connector of each adapter is a single dut connector.

6. The burn-in apparatus of claim 1 wherein said at least one adapter is a plurality of adapters, each adapter having a dut connector electrically connected to contacts of at least two of said load zones of said circuit substrate.

7. The burn-in apparatus of claim 1 wherein said at least one adapter is a single adapter having a dut connector electrically connected to contacts of said plurality of load zones of said circuit substrate.