CN214473693U

CN214473693U - Dielectric filter test equipment

Info

Publication number: CN214473693U
Application number: CN202120269012.XU
Authority: CN
Inventors: 吴泽景; 黄庆焕; 孔唯同; 陈扬; 艾晨霞
Original assignee: Mobi Antenna Technologies Shenzhen Co Ltd; Shenzhen Shengyu Wisdom Network Technology Co Ltd; Mobi Technology Xian Co Ltd; Mobi Technology Shenzhen Co Ltd; Xian Mobi Antenna Technology Engineering Co Ltd; Mobi Telecommunications Technologies Jian Co Ltd
Current assignee: Mobi Antenna Technologies Shenzhen Co Ltd; Shenzhen Shengyu Wisdom Network Technology Co Ltd; Mobi Technology Xian Co Ltd; Mobi Technology Shenzhen Co Ltd; Xian Mobi Antenna Technology Engineering Co Ltd; Mobi Telecommunications Technologies Jian Co Ltd
Priority date: 2021-01-29
Filing date: 2021-01-29
Publication date: 2021-10-22
Anticipated expiration: 2031-01-29

Abstract

The utility model provides a dielectric filter test equipment relates to radio frequency communication technical field, the utility model provides a dielectric filter test equipment includes: the device comprises a tool mechanism, a testing mechanism and a grabbing mechanism, wherein the tool mechanism is used for fixing a detected dielectric filter, and the testing mechanism is arranged on the tool mechanism; the grabbing mechanism comprises a transmission assembly and a grabbing assembly, the transmission assembly is in transmission connection with the grabbing assembly to drive the grabbing assembly to place or grab the medium filter to the tool mechanism. The utility model provides a dielectric filter test equipment has alleviated the comparatively low technical problem of test mode efficiency among the correlation technique.

Description

Dielectric filter test equipment

Technical Field

The utility model belongs to the technical field of the radio frequency communication technique and specifically relates to a dielectric filter test equipment is related to.

Background

In the filter industry, the produced products are subjected to a strict ATE (Automatic test equipment) test to ensure the performance of the products. At present traditional mode is all that the manual scanning product bar code, puts into the frock with the product in, connects to carry out the test with the vector net, takes out again after the test is qualified, still need take out when the test is bad categorised, and the efficiency is comparatively low and easy categorised mistake leads to the compounding, influences the product percent of pass.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a dielectric filter test equipment to alleviate the comparatively low technical problem of test mode efficiency among the correlation technique.

The utility model provides a dielectric filter test equipment includes: the device comprises a tool mechanism, a testing mechanism and a grabbing mechanism, wherein the tool mechanism is used for fixing a detected dielectric filter, and the testing mechanism is arranged on the tool mechanism;

the grabbing mechanism comprises a transmission assembly and a grabbing assembly, wherein the transmission assembly is in transmission connection with the grabbing assembly so as to drive the grabbing assembly to place or grab the dielectric filter on the tooling mechanism.

Further, the tooling mechanism comprises a tooling base and a fixed block, the testing mechanism comprises a detection module, and the fixed block and the detection module are respectively installed on the tooling base.

Further, the tooling mechanism further comprises a tooling pressing plate and a pressing plate driving assembly, wherein the pressing plate driving assembly is in transmission connection with the tooling pressing plate so as to drive the tooling pressing plate to compress or loosen the dielectric filter arranged on the tooling base.

Further, the pressing plate driving assembly comprises a pressing plate X-directional driving piece, a pressing plate Z-directional transmission frame and a pressing plate Z-directional driving piece, the pressing plate X-directional driving piece is in transmission connection with the pressing plate Z-directional transmission frame, and the pressing plate Z-directional driving piece is installed on the pressing plate Z-directional transmission frame and is in transmission connection with the tool pressing plate.

Further, the transmission assembly comprises an X-direction transmission assembly, a Y-direction transmission assembly and a Z-direction transmission assembly, the Y-direction transmission assembly is in transmission connection with the X-direction transmission assembly, the X-direction transmission assembly is in transmission connection with the Z-direction transmission assembly, and the Z-direction transmission assembly is in transmission connection with the grabbing assembly.

Further, X is to drive assembly including X to the transmission frame, and install in X is to the first motor and the first ball of transmission frame, Y is to drive assembly including second motor and second ball, Z is to drive assembly including the cylinder, the second motor with the second ball transmission is connected, the second ball with X is to the transmission frame transmission connection, first motor with first ball transmission is connected, first ball with the cylinder transmission is connected, the cylinder with it is connected to snatch the subassembly transmission.

Further, the grabbing component comprises a sucker and a vacuum generator, wherein the sucker is installed at the driving end of the air cylinder and is communicated with the vacuum generator.

Further, the dielectric filter testing equipment further comprises a conveying mechanism, and the conveying mechanism is used for conveying the dielectric filter.

Further, conveying mechanism includes conveyor components, spacing platform and turnover frock, conveyor components with spacing transmission of platform is connected, the turnover frock is used for bearing dielectric filter, and with spacing can dismantle the connection.

Further, the dielectric filter test equipment further comprises a scanning mechanism, and the scanning mechanism is used for scanning the bar code on the dielectric filter and transmitting the bar code to the test mechanism.

The utility model provides a dielectric filter test equipment includes: the device comprises a tool mechanism, a testing mechanism and a grabbing mechanism, wherein the tool mechanism is used for fixing a detected dielectric filter, and the testing mechanism is arranged on the tool mechanism; the grabbing mechanism comprises a transmission assembly and a grabbing assembly, the transmission assembly is in transmission connection with the grabbing assembly to drive the grabbing assembly to place or grab the medium filter to the tool mechanism. The utility model provides a dielectric filter test equipment is at test dielectric filter's in-process, and drive assembly drives and snatchs the subassembly motion, makes and snatchs the subassembly and places dielectric filter in fixture, and fixture fixes dielectric filter, and test mechanism tests the dielectric filter in the fixture, accomplishes the test back, and drive assembly drives and snatchs the subassembly motion, takes away the dielectric filter who accomplishes the test in fixture to place in the assigned position.

Compare with the mode of artifical test in the correlation technique, the utility model provides a dielectric filter test equipment goes up unloading and test automatically, has improved efficiency of software testing.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention or the related art, the drawings required to be used in the description of the embodiments or the related art will be briefly introduced below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a dielectric filter testing apparatus provided in an embodiment of the present invention;

FIG. 2 is an enlarged view of a portion of FIG. 1 at A;

fig. 3 is a top view of a dielectric filter testing apparatus provided in an embodiment of the present invention;

fig. 4 is a top view of a tooling mechanism in a dielectric filter testing apparatus according to an embodiment of the present invention.

Icon: 100-a tooling mechanism; 110-a tooling base; 120-fixed block; 130-tool pressing plate; 140-platen drive assembly; 141-platen X-direction drive; 142-press plate Z-direction transmission frame; 210-a detection module; 220-test vector net; 300-a gripping mechanism; a 310-X direction transmission component; a 320-Y direction transmission component; a 330-Z direction transmission component; 400-a transport mechanism; 500-a frame; 600-temporary storage module.

Detailed Description

The technical solution of the present invention will be described clearly and completely with reference to the accompanying drawings, and obviously, the described embodiments are some, but not all embodiments of the present invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

As shown in fig. 1 to 4, the embodiment of the present invention provides a dielectric filter test apparatus, including: the device comprises a tool mechanism 100, a testing mechanism and a grabbing mechanism 300, wherein the tool mechanism 100 is used for fixing a detected dielectric filter, and the testing mechanism is arranged on the tool mechanism 100; the grabbing mechanism 300 comprises a transmission component and a grabbing component, wherein the transmission component is in transmission connection with the grabbing component so as to drive the grabbing component to place or grab the dielectric filter to the tool mechanism 100.

The embodiment of the utility model provides a dielectric filter test equipment still includes frame 500, and tool equipment 100 all installs in the up end of frame 500 with the drive assembly who snatchs in the mechanism 300, snatchs the unit mount in drive assembly's motion end to it is relative with the upper end of frame 500, in order to place or snatch dielectric filter to tool equipment 100.

As shown in fig. 3 and 4, the tooling mechanism 100 includes a tooling base 110 and a fixed block 120, the testing mechanism includes a testing module 210, and the fixed block 120 and the testing module 210 are respectively mounted on the tooling base 110.

Specifically, the number of the tooling mechanisms 100 is multiple, the tooling bases 110 in the multiple tooling mechanisms 100 are distributed at intervals along the X direction, and each tooling base 110 is provided with a fixed block 120 and a detection module 210. The testing mechanism further comprises a testing vector network 220, a testing cable and a testing computer, wherein the testing computer is connected with the testing vector network 220, and the testing cable is respectively connected with the detecting module 210 and the testing vector network 220. In the testing process, the transmission assembly drives the grabbing assembly to move, the dielectric filter is grabbed to the tooling base 110, the fixed block 120 on the tooling base 110 limits the dielectric filter, the detection module 210 detects the dielectric filter and transmits the detection structure to the testing computer, the grabbing mechanism 300 takes the detected dielectric filter off the tooling base 110 after the test is finished, qualified products and unqualified products are placed at corresponding positions according to the detection result, and the detection and the feeding and discharging are automatically finished.

Further, the tooling mechanism 100 further comprises a tooling press plate 130 and a press plate driving assembly 140, wherein the press plate driving assembly 140 is in transmission connection with the tooling press plate 130 so as to drive the tooling press plate 130 to press or loosen the dielectric filter arranged on the tooling base 110.

Specifically, the plurality of tool press plates 130 are matched with the plurality of tool bases 110 in a one-to-one correspondence manner, and each tool press plate 130 is in transmission connection with one press plate driving assembly 140, so as to drive the tool press plates 130 to compress or release the dielectric filters arranged on the corresponding tool bases 110. In the testing process, the grabbing component places the dielectric filter on the tooling base 110, the tooling pressing plate 130 corresponding to the tooling base 110 with the dielectric filter is driven by the pressing plate driving component 140 to compress the dielectric filter, so that the dielectric filter is ensured to be fully contacted with parts on the detection module 210, and the testing accuracy is ensured.

Further, the pressing plate driving assembly 140 includes a pressing plate X-direction driving member 141, a pressing plate Z-direction transmission frame 142 and a pressing plate Z-direction driving member, the pressing plate X-direction driving member 141 is in transmission connection with the pressing plate Z-direction transmission frame 142, and the pressing plate Z-direction driving member is installed on the pressing plate Z-direction transmission frame 142 and is in transmission connection with the tool pressing plate 130.

Specifically, the pressing plate X-direction driving part 141 comprises a pressing plate X-direction cylinder, the pressing plate Z-direction driving part comprises a pressing plate Z-direction cylinder, the pressing plate X-direction cylinder is mounted on the frame 500, the driving end is in transmission connection with the pressing plate Z-direction transmission frame 142, the pressing plate Z-direction transmission frame 142 is in sliding connection with the frame 500, the pressing plate Z-direction cylinder is arranged along the vertical direction and mounted on the pressing plate Z-direction transmission frame 142, and the tool pressing plate 130 is mounted on the driving end of the pressing plate Z-direction cylinder. After the grabbing mechanism 300 places the dielectric filter on the tooling base 110, the pressing plate X drives the tooling pressing plate 130 to move to the upper side of the tooling base 110 to the air cylinder, and the pressing plate Z drives the tooling pressing plate 130 to move downwards to press on the dielectric filter, so that the dielectric filter is in full contact with the detection module 210 on the tooling base 110, and the accuracy of the test is ensured.

Furthermore, the transmission assembly comprises an X-direction transmission assembly, a Y-direction transmission assembly and a Z-direction transmission assembly, the Y-direction transmission assembly is in transmission connection with the X-direction transmission assembly, the X-direction transmission assembly is in transmission connection with the Z-direction transmission assembly, and the Z-direction transmission assembly is in transmission connection with the grabbing assembly.

The X can drive the grabbing component to move along the X direction to the transmission component, the Y can drive the grabbing component to move along the Y direction to the transmission component, the Z can drive the grabbing component to move along the Z direction to the transmission component, and the X can drive the grabbing component to move along the Z direction to the transmission component, the Y can drive the grabbing component to move along the Z direction to the transmission component and the Z drives the grabbing component to move, so that the grabbing component can convey the dielectric filter at the designated position to the tooling base 110, or convey the dielectric filter which is detected on the tooling base 110 to the designated position, thereby realizing automatic feeding and discharging and improving the detection efficiency.

Further, X includes X to the drive assembly to and install in X to the first motor and the first ball of drive assembly, Y includes second motor and second ball to the drive assembly, Z includes the cylinder to the drive assembly, the second motor is connected with the transmission of second ball, second ball is connected with X to the drive assembly transmission, first motor is connected with first ball transmission, first ball is connected with the cylinder transmission, the cylinder with snatch the subassembly transmission and be connected.

Specifically, the second ball is installed in frame 500, and set up along Y, the lead screw transmission in second motor and the second ball is connected, nut and X in the second ball are connected to the one end of transmission frame, X passes through slide rail and slider and frame 500 sliding connection to the other end of transmission frame, X sets up along X to the transmission frame, and be located tooling base 110's top, first ball sets up and installs in X to the transmission frame along X, first motor is installed in X to the transmission frame and is connected with the lead screw transmission in the first ball, nut and the Z in the first ball are connected to the transmission frame, the cylinder is installed in Z to the transmission frame, and flexible end is located the below, snatch the flexible end of subassembly installation in the cylinder. The second motor drives the second ball screw to drive the first ball screw, the cylinder and the grabbing component move along the Y direction, the first motor drives the first ball screw to drive the cylinder and the grabbing component move along the X direction, the cylinder drives the grabbing component to move along the Z direction, and therefore the three-direction movement driving of the grabbing component is achieved, the grabbing component enables the medium filter at the specified position to be grabbed onto the tooling base 110, or the medium filter which completes detection on the tooling base 110 is grabbed onto the specified position, automatic feeding and discharging are achieved, detection efficiency is improved, the accuracy of grabbing component movement can be improved due to the arrangement of the first ball screw and the second ball screw, and grabbing and placing of the grabbing component are higher in accuracy.

As another implementation mode, the X-direction transmission assembly comprises an X-direction transmission frame, and a first motor and a first belt transmission assembly which are installed on the X-direction transmission frame, the Y-direction transmission assembly comprises a second motor and a second belt transmission assembly, the Z-direction transmission assembly comprises an air cylinder, the first motor is in transmission connection with the first belt transmission assembly, the first belt transmission assembly is in transmission connection with the air cylinder, the second motor is in transmission connection with the second belt transmission assembly, and the second belt transmission assembly is in transmission connection with the X-direction transmission frame.

Specifically, the second belt drive assembly is installed in frame 500, and set up along Y, the second motor is connected with the belt pulley transmission among the second belt drive assembly, drive belt among the second belt drive assembly is connected to the one end of driving frame with X, X passes through slide rail and slider and frame 500 sliding connection to the other end of driving frame, X sets up along X to the driving frame, and be located the top of frock base 110, first belt drive assembly sets up and installs in X to the driving frame along X, first motor is installed in X to the driving frame and is connected with the belt pulley transmission among the first belt drive assembly, drive belt and Z among the first belt drive assembly are connected to the driving frame, the cylinder is installed in Z to the driving frame, and flexible end is located the below, it installs in the flexible end of cylinder to snatch the subassembly. In the testing process, second motor drive second area drive assembly drives first area drive assembly, the cylinder with snatch the subassembly and move along Y to, first motor drive first area drive assembly drives the cylinder and snatchs the subassembly and move along X to, the cylinder drive snatchs the subassembly and moves along Z to, thereby realize the drive to snatching the three direction motion of subassembly, the messenger snatchs the subassembly and can carry the dielectric filter of assigned position department to fixture base 110, perhaps carry the dielectric filter who accomplishes the detection on fixture base 110 to the assigned position, thereby realize automatic unloading, and the detection efficiency is improved.

Further, the grabbing component comprises a sucking disc and a vacuum generator, wherein the sucking disc is installed at the driving end of the air cylinder and is communicated with the vacuum generator.

Specifically, the sucking disc adopts three-head sucking disc, and the flexible end and the sucking disc transmission of cylinder are connected, and vacuum generator installs on X to removing the frame to communicate with the sucking disc for produce the negative pressure in the sucking disc. In the detection process, the dielectric filter is sucked up through the sucking disc, the sucking disc loosens the dielectric filter after the dielectric filter is conveyed to the specified position, the sucking disc takes up the dielectric filter through negative pressure, other acting forces are not generated on the dielectric filter, and therefore damage to the dielectric filter can be reduced.

Specifically, the conveying mechanism is mounted to the chassis 500, and conveys the dielectric filter in the X direction. In the detection process, the conveying mechanism conveys the undetected dielectric filter to a position opposite to the tooling base 110, the X-direction transmission assembly 310, the Y-direction transmission assembly 320 and the Z-direction transmission assembly 330 are matched with the driving sucker to take the dielectric filter on the conveying mechanism to the tooling base 110, the detected and qualified dielectric filter on the tooling base 110 is taken to the conveying mechanism again, and the conveying mechanism conveys the detected dielectric filter to the next station. The conveying mechanism is arranged to realize automatic feeding and discharging of the dielectric filter testing equipment, so that the detection efficiency can be further improved.

Further, conveying mechanism includes conveyor components, spacing platform and turnover frock, and conveyor components is connected with spacing transmission of platform, and the turnover frock is used for bearing dielectric filter to can dismantle with spacing platform and be connected.

Specifically, conveying component includes two belt drive components, and two belt drive components are along Y to interval distribution to all along X to the motion, are equipped with a plurality of spacing platforms between two belt drive components, a plurality of spacing platforms are along the circumference interval distribution of the drive belt in the belt drive component, and are connected with two drive belts, and driving motor is connected with two belt drive component transmissions. The turnover tool can be placed on the limiting table and taken down from the limiting table. In the detection process, the belt transmission assembly drives the turnover tool to move through the limiting block, so that the dielectric filter is conveyed to a position to be tested, the grabbing assembly grabs the dielectric filter on the turnover tool onto the tool base 110, after the test is completed, the qualified dielectric filter is grabbed back to the turnover tool, and after the dielectric filter on the turnover tool is completely tested, the belt transmission assembly conveys the tested dielectric filter out, so that the automatic conveying of products is completed.

Further, the dielectric filter test equipment further comprises a test scanning mechanism and a product temporary storage module 600, the test scanning mechanism and the product temporary storage module 600 are both installed on the rack 500 and are arranged opposite to the conveying mechanism 400, when the grabbing component grabs the dielectric filter on the conveying mechanism 400 and conveys the dielectric filter to the tooling base 110, the grabbing component drives the dielectric filter to pass through the test scanning mechanism, the test scanning mechanism scans the bar code on the side face of the dielectric filter, correlates the data of the dielectric filter tested by the detection module 210, correlates the qualified dielectric filter with a packaging label, and directly uploads the data to a background system, so that the data butt joint with the whole production system is guaranteed, and the detection accuracy is improved. When detecting unqualified dielectric filter, snatch mechanism 300 and remove unqualified dielectric filter to module 600 of keeping in, unqualified dielectric filter is unified to be placed in module 600 of keeping in, and the later stage of being convenient for is unified to be handled.

The embodiment of the utility model provides a dielectric filter test equipment includes: the device comprises a tool mechanism 100, a testing mechanism and a grabbing mechanism 300, wherein the tool mechanism 100 is used for fixing a detected dielectric filter, and the testing mechanism is arranged on the tool mechanism 100; the grabbing mechanism 300 comprises a transmission component and a grabbing component, wherein the transmission component is in transmission connection with the grabbing component so as to drive the grabbing component to place or grab the dielectric filter to the tool mechanism 100. The embodiment of the utility model provides a dielectric filter test equipment is at test dielectric filter's in-process, and drive assembly drives and snatchs the subassembly motion, makes and snatchs the subassembly and place dielectric filter on frock mechanism 100, and frock mechanism 100 is fixed dielectric filter, and testing mechanism tests dielectric filter on to frock mechanism 100, accomplishes the test back, and drive assembly drives and snatchs the subassembly motion, takes away the dielectric filter who accomplishes the test on frock mechanism 100, and places in the assigned position.

Compare with artifical test in the correlation technique, the embodiment of the utility model provides a dielectric filter test equipment goes up unloading and test automatically, has improved efficiency of software testing.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention.

Claims

1. A dielectric filter test apparatus, comprising: the device comprises a tooling mechanism (100), a testing mechanism and a grabbing mechanism (300), wherein the tooling mechanism (100) is used for fixing the detected dielectric filter, and the testing mechanism is installed on the tooling mechanism (100);

the grabbing mechanism (300) comprises a transmission assembly and a grabbing assembly, wherein the transmission assembly is in transmission connection with the grabbing assembly so as to drive the grabbing assembly to place or grab the medium filter to the tooling mechanism (100).

2. The dielectric filter testing device according to claim 1, wherein the tooling mechanism (100) comprises a tooling base (110) and a fixed block (120), the testing mechanism comprises a detection module (210), and the fixed block (120) and the detection module (210) are respectively mounted on the tooling base (110).

3. The dielectric filter testing equipment according to claim 2, wherein the tooling mechanism (100) further comprises a tooling press plate (130) and a press plate driving assembly (140), and the press plate driving assembly (140) is in transmission connection with the tooling press plate (130) to drive the tooling press plate (130) to press or loosen the dielectric filter placed on the tooling base (110).

4. The dielectric filter test equipment as claimed in claim 3, wherein the pressing plate driving assembly (140) comprises a pressing plate X-direction driving member (141), a pressing plate Z-direction transmission frame (142) and a pressing plate Z-direction driving member, the pressing plate X-direction driving member (141) is in transmission connection with the pressing plate Z-direction transmission frame (142), and the pressing plate Z-direction driving member is mounted on the pressing plate Z-direction transmission frame (142) and is in transmission connection with the tooling pressing plate (130).

5. The dielectric filter testing apparatus according to claim 1, wherein the transmission assembly comprises an X-direction transmission assembly (310), a Y-direction transmission assembly (320) and a Z-direction transmission assembly (330), the Y-direction transmission assembly (320) is in transmission connection with the X-direction transmission assembly (310), the X-direction transmission assembly (310) is in transmission connection with the Z-direction transmission assembly (330), and the Z-direction transmission assembly (330) is in transmission connection with the grabbing assembly.

6. The dielectric filter testing apparatus of claim 5, wherein the X-direction transmission assembly (310) comprises an X-direction transmission frame, and a first motor and a first ball screw mounted on the X-direction transmission frame, the Y-direction transmission assembly (320) comprises a second motor and a second ball screw, the Z-direction transmission assembly (330) comprises an air cylinder, the second motor is in transmission connection with the second ball screw, the second ball screw is in transmission connection with the X-direction transmission frame, the first motor is in transmission connection with the first ball screw, the first ball screw is in transmission connection with the air cylinder, and the air cylinder is in transmission connection with the grabbing assembly.

7. The dielectric filter testing apparatus of claim 6, wherein the grasping assembly includes a suction cup and a vacuum generator, the suction cup being mounted at a drive end of the cylinder and in communication with the vacuum generator.

8. The dielectric filter testing apparatus according to any one of claims 1 to 7, further comprising a conveying mechanism for conveying the dielectric filter.

9. The dielectric filter test equipment according to claim 8, wherein the conveying mechanism comprises a conveying assembly, a limiting table and a turnover tool, the conveying assembly is in transmission connection with the limiting table, and the turnover tool is used for bearing the dielectric filter and is detachably connected with the limiting table.

10. The dielectric filter testing apparatus of claim 1, further comprising a scanning mechanism for scanning a barcode on the dielectric filter and transmitting to the testing mechanism.