Multi-station displacement-type glass phase light detection equipment
The design of the limiting component enables rapid disassembly and maintenance of the multi-workstation displacement-type glass phase light detection equipment, solving the problems of long disassembly time and easy damage caused by traditional bolt fastening methods, and improving maintenance efficiency and equipment stability.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SUQIAN SHAOCHEN INTELLIGENT TECH CO LTD
- Filing Date
- 2025-05-26
- Publication Date
- 2026-06-30
AI Technical Summary
Traditional multi-workstation displacement-type glass phase light detection equipment uses bolts to fix the protective side plates, which makes the disassembly process time-consuming and cumbersome during maintenance. Frequent disassembly can also lead to stripped threads and deformed holes, affecting the difficulty of maintenance and the operating performance of the equipment.
The system employs a limiting assembly, including a protective side plate, a protruding plate, a fixed base, and an H-shaped limiting block. By rotating the threaded sleeve and the limiting block, the protective side plate can be quickly opened and closed, avoiding the need to disassemble the bolts one by one.
It improves equipment maintenance and repair efficiency, reduces the workload of staff, avoids problems such as thread stripping and hole deformation, and ensures stable equipment operation performance.
Smart Images

Figure CN224436150U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of measurement technology, and in particular to a multi-workstation displacement-type glass phase light detection device. Background Technology
[0002] In the glass manufacturing and processing industry, multi-workstation displacement-type glass phase light inspection equipment has become a core device for ensuring the quality of glass products due to its high-precision inspection capabilities.
[0003] Traditional testing equipment typically uses bolts to fasten protective side panels. When precision components such as the transfer mechanism, imaging module, and light source system inside the equipment malfunction, maintenance personnel need to use various sizes of wrenches, screwdrivers, and other tools to disassemble the side panels. Due to the large number and dense distribution of bolts on the side panels, each disassembly process is time-consuming, and the repeated disassembly and reassembly procedures are cumbersome, seriously affecting maintenance efficiency. In addition, frequent bolt disassembly can easily lead to problems such as stripped threads and deformation of side panel holes, which not only increases the difficulty of maintenance but may also affect the operating performance of the equipment due to a decrease in the sealing performance of the side panels. Utility Model Content
[0004] The purpose of this utility model is to at least solve one of the technical problems existing in the prior art, and to provide a multi-workstation displacement glass phase light detection device. This device can solve the problem that the protective side plates are generally fixed by bolt fastening. When precision components such as the transfer mechanism, imaging module, and light source system inside the equipment malfunction, maintenance personnel need to use various sizes of wrenches, screwdrivers and other tools to disassemble the side plates. Because there are many bolts on the side plates and they are densely distributed, a single disassembly process is time-consuming and requires repeated disassembly and reassembly, which is cumbersome and seriously affects maintenance efficiency. In addition, frequent bolt disassembly can easily lead to problems such as stripped threads and deformation of side plate holes, which not only increases the difficulty of maintenance, but may also affect the operating performance of the equipment due to the decrease in the sealing performance of the side plates.
[0005] To achieve the above objectives, this utility model provides the following technical solution: a multi-station displacement-type glass phase light detection device, comprising a short-side detection station, a front and back detection station, a long-side detection station, and a phase light detection device body, wherein limit components are provided on both sides of the phase light detection device body;
[0006] The limiting assembly includes a protective side plate, a protruding plate, a fixed seat, and two H-shaped limiting blocks. The fixed seat is fixedly installed on the outer wall of one side of the main frame of the phase light detection equipment. The outer wall of the lower end of the protective side plate is rotatably connected to the upper groove of the fixed seat. The protruding plate is fixedly installed on the upper outer wall of one side of the main frame of the phase light detection equipment. The outer walls of the two protrusions on both ends of the main frame of the phase light detection equipment are provided with T-shaped block slots. The upper outer wall of the protective side plate is provided with the same two T-shaped block slots. Rotary threaded rod sleeves are rotatably connected to the outer walls of both sides of the protruding plate.
[0007] The two ends of the two H-shaped limiting blocks are respectively engaged with the H-shaped block grooves formed by the T-shaped block grooves on the corresponding protective side plates and the main frame of the phase light detection equipment. The outer walls on both sides of the upper protrusion of the protective side plate are provided with second limiting block grooves, and the inner walls on both sides of the lower end of the protrusion are provided with first limiting block grooves. The two first limiting block grooves are slidably connected with limiting blocks, and the two first limiting block grooves are provided with rotating threaded rods. The two limiting components are respectively set on both sides of the main frame of the phase light detection equipment.
[0008] Preferably, the outer wall of the protective side plate is slidably connected to the inside of one side of the main frame of the phase light detection equipment, and the outer wall of the upper protrusion of the protective side plate is slidably connected to the inside of the groove at the lower end of the protrusion.
[0009] The two T-shaped block slots on the protective side plate are respectively used in conjunction with the T-shaped block slots on the main frame of the corresponding phase light detection equipment.
[0010] Preferably, the ends of the two rotating threaded rod sleeves near the convex plate both extend rotatably into the interior of the first limiting block groove, and the ends of the two rotating threaded rods near the limiting block are respectively rotatably connected to the outer wall of the corresponding limiting block;
[0011] Among them, the ends of the two limiting blocks near the second limiting block grooves are slidably extended into the lower end of the convex plate and are slidably connected to the interior of the corresponding second limiting block grooves, and the ends of the two rotating threaded rods away from the limiting blocks are respectively connected to the interior threads of the corresponding rotating threaded rod sleeves.
[0012] Preferably, the short-side detection station is installed inside the left side of the main frame of the phase light detection equipment;
[0013] The long-side inspection station is installed inside the right side of the main frame of the phase light inspection equipment, while the front and back inspection stations are installed inside the middle of the main frame of the phase light inspection equipment.
[0014] Preferably, a short-side detection station cabinet door is installed on the outer left side of the main frame of the phase light detection equipment;
[0015] The short-side inspection station cabinet door is used in conjunction with the short-side inspection station, while the long-side inspection station cabinet door is installed on the outer right side of the main frame of the phase light inspection equipment.
[0016] Preferably, the long-side detection station cabinet door is used in conjunction with the long-side detection station, and the front and back detection station cabinet doors are installed on the outer wall of the middle of the main frame of the phase light detection equipment.
[0017] The front and back inspection station cabinet door is used in conjunction with the front and back inspection station, and four casters are installed at the lower end of the main frame of the phase light inspection equipment.
[0018] Compared with the prior art, the beneficial effects of this utility model are:
[0019] 1. This multi-workstation displacement-type glass phase light detection equipment utilizes a rotating threaded sleeve in the limiting assembly. Since the rotating threaded sleeve is threadedly connected to the rotating threaded rod, the rotating threaded rod causes the limiting block to slide within the first limiting block groove. When the limiting block slides away from the rotating threaded sleeve, it is pulled out from the second limiting block groove. At this point, the protective side plate can rotate around the fixed base, thus opening the protective side plate and fully exposing the interior of the equipment. This facilitates comprehensive maintenance and repair work on all internal components, including the various detection stations and the limiting assembly, by personnel. This avoids the need to disassemble bolts one by one using tools, effectively reducing the workload of personnel while improving the maintenance and repair efficiency of the main body of the phase light detection equipment. Attached Figure Description
[0020] The present invention will be further described below with reference to the accompanying drawings and embodiments:
[0021] Figure 1 This is a three-dimensional structural diagram of the present invention;
[0022] Figure 2 This is a schematic diagram of the external structure of the protective side plate of this utility model;
[0023] Figure 3 This is a schematic diagram of the external structure of the limiting block of this utility model;
[0024] Figure 4 This utility model Figure 2 A structural schematic diagram of the enlarged view at point A in the middle.
[0025] Reference numerals: 1. Short side inspection station; 2. Front and back inspection station; 3. Long side inspection station; 4. Protective side plate; 5. Casters; 6. Short side inspection station cabinet door; 7. Front and back inspection station cabinet door; 8. Long side inspection station cabinet door; 9. H-type limit block; 10. Rotating threaded rod sleeve; 11. T-shaped block slot; 12. Protruding plate; 13. Fixed base; 14. Limit block; 15. Rotating threaded rod; 16. First limit block slot; 17. Second limit block slot; 18. Main body of phase light inspection equipment. Detailed Implementation
[0026] This section will describe in detail the specific embodiments of the present utility model. The preferred embodiments of the present utility model are shown in the accompanying drawings. The purpose of the drawings is to supplement the textual description with graphics, so that people can intuitively and vividly understand each technical feature and the overall technical solution of the present utility model, but they should not be construed as limiting the scope of protection of the present utility model.
[0027] In the description of this utility model, it should be understood that the directional descriptions, such as up, down, front, back, left, right, etc., indicate the directional or positional relationship based on the directional or positional relationship shown in the accompanying drawings. They are only for the convenience of describing this utility model and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on this utility model.
[0028] In the description of this utility model, terms such as greater than, less than, and exceeding are understood to exclude the stated number, while terms such as above, below, and within are understood to include the stated number. The use of terms like "first" and "second" is merely for distinguishing technical features and should not be construed as indicating or implying relative importance, or implicitly indicating the quantity or sequence of the indicated technical features.
[0029] In the description of this utility model, unless otherwise explicitly defined, terms such as "setting," "installation," and "connection" should be interpreted broadly, and those skilled in the art can reasonably determine the specific meaning of the above terms in this utility model in conjunction with the specific content of the technical solution.
[0030] Please see Figure 1-4 This utility model provides a technical solution: a multi-workstation displacement glass phase light detection device, including a short side detection station 1, a front and back side detection station 2, a long side detection station 3, and a phase light detection device body 18;
[0031] Limiting components are provided on both sides of the main body 18 of the phase light detection device;
[0032] The limiting assembly includes a protective side plate 4, a protruding plate 12, a fixing seat 13, and two H-shaped limiting blocks 9. The fixing seat 13 is fixedly installed on the outer wall of one side of the frame of the phase light detection equipment body 18. The outer wall of the lower fixing rod of the protective side plate 4 is rotatably connected to the inner groove of the upper groove of the fixing seat 13. The outer wall of the protective side plate 4 is slidably connected to the inner side of one side of the frame of the phase light detection equipment body 18. The protruding plate 12 is fixedly installed on the upper outer wall of one side of the frame of the phase light detection equipment body 18. The outer wall of the upper protrusion of the protective side plate 4 is connected to the lower protruding plate 12. The end slots are internally slidably connected. T-shaped block slots 11 are provided on the outer walls of the two protrusions at both ends of the frame of the phase light detection equipment body 18. Two similar T-shaped block slots 11 are provided on the outer wall of the upper end of the protective side plate 4. Rotating threaded rod sleeves 10 are rotatably connected to the outer walls of both sides of the protrusion plate 12. The two T-shaped block slots 11 on the protective side plate 4 respectively cooperate with the corresponding T-shaped block slots 11 on the frame of the phase light detection equipment body 18. The two ends of the two H-shaped limiting blocks 9 are respectively connected to the corresponding protective side plates 4. The H-shaped block groove formed by the T-shaped block slot 11 on the frame of the phase light detection equipment body 18 is engaged internally. The outer walls of both sides of the upper protrusion of the protective side plate 4 are provided with second limiting block grooves 17, and the inner walls of both sides of the lower end of the protrusion plate 12 are provided with first limiting block grooves 16. The interiors of the two first limiting block grooves 16 are slidably connected to limiting blocks 14. The ends of the two rotating threaded rod sleeves 10 near the protrusion plate 12 are rotatably extended into the interiors of the first limiting block grooves 16. The interiors of the two first limiting block grooves 16 are provided with rotating threaded rods 15. The ends of the two rotating threaded rods 15 near the limiting blocks 14 are rotatably connected to the outer walls of the corresponding limiting blocks 14. The ends of the two limiting blocks 14 near the second limiting block grooves 17 are slidably extended into the interiors of the lower end of the protrusion plate 12 and are slidably connected to the interiors of the corresponding second limiting block grooves 17. The ends of the two rotating threaded rods 15 away from the limiting blocks 14 are threadedly connected to the interiors of the corresponding rotating threaded rod sleeves 10. The two limiting components are respectively set on both sides of the frame of the phase light detection equipment body 18.
[0033] The short-side inspection station 1 is installed inside the left side of the main frame 18 of the phase light inspection equipment; the long-side inspection station 3 is installed inside the right side of the main frame 18 of the phase light inspection equipment; the front and back inspection station 2 is installed inside the middle of the main frame 18 of the phase light inspection equipment; a short-side inspection station cabinet door 6 is installed on the left outer wall of the main frame 18 of the phase light inspection equipment, which works in conjunction with the short-side inspection station 1; a long-side inspection station cabinet door 8 is installed on the right outer wall of the main frame 18 of the phase light inspection equipment, which works in conjunction with the long-side inspection station 3; a front and back inspection station cabinet door 7 is installed on the middle outer wall of the main frame 18 of the phase light inspection equipment, which works in conjunction with the front and back inspection station 2; and four casters 5 are installed at the lower end of the main frame 18 of the phase light inspection equipment.
[0034] Furthermore, when using this device, during operation, the four casters 5 at the lower end of the frame of the phase light detection equipment body 18 are first used to move the equipment to the designated working position to complete the equipment positioning. When performing glass detection operations, the operator directly opens the cabinet door of the corresponding detection station. If the short side of the glass needs to be detected, the short side detection station cabinet door 6 is opened, and the glass is placed in the detection area of the short side detection station 1. If the front and back sides of the glass need to be detected, the front and back detection station cabinet door 7 is opened, and the glass is placed in the front and back detection station 2. If the long side needs to be detected, the long side detection station cabinet door is opened. Door 8: Place the glass into the long-side inspection station 3. After placement, close the corresponding cabinet door to ensure a stable testing environment. At this time, each inspection station begins operation. The short-side inspection station 1 inspects the short side of the glass, acquiring relevant data through its internal testing device. The front and back inspection station 2 determines the orientation of the glass and surface defects. The long-side inspection station 3 completes the testing and analysis of various indicators of the long side of the glass. During this process, the protective side panel 4 remains closed. Through its cooperation with the convex plate 12, the fixed seat 13, and the H-shaped limit block 9, it forms a protective barrier inside the equipment, preventing... To prevent external factors from interfering with the detection and ensure its accuracy and stability, when maintenance and repair of the internal structure of the phase light detection equipment 18 are required, the H-shaped limiting block 9 is first removed from the H-shaped block slot formed by the T-shaped block slot 11 on the protective side plate 4 and the T-shaped block slot 11 on the phase light detection equipment 18 using tools. Then, the operator rotates the threaded rod sleeve 10. Since the threaded rod sleeve 10 is threadedly connected to the threaded rod 15, rotating the threaded rod 15 will cause the limiting block 14 to slide within the first limiting block slot 16. When the limiting block 14 moves away from the threaded rod... When sleeve 10 slides in the direction of movement, it will be pulled out from the second limit block groove 17. At this time, the protective side plate 4 can rotate around the fixed seat 13 and slide in the groove at the lower end of the protruding plate 12, thereby opening the protective side plate 4 and fully exposing the inside of the equipment. This makes it convenient for staff to carry out comprehensive maintenance and repair work on the internal components of the equipment, including the various testing stations and limit components. After the repair is completed, rotate the threaded rod sleeve 10 in the opposite direction to make the limit block 14 re-insert into the second limit block groove 17, fix the protective side plate 4 back to its original position, and lock it into the H-type limit block 9 to restore the equipment's protection and limit functions.
[0035] By rotating the threaded sleeve 10 in the limiting assembly, since the threaded sleeve 10 is threadedly connected to the threaded rod 15, the threaded rod 15 will drive the limiting block 14 to slide in the first limiting block groove 16. When the limiting block 14 slides away from the threaded sleeve 10, it will be pulled out from the second limiting block groove 17. At this time, the protective side plate 4 can rotate around the fixed seat 13, thereby opening the protective side plate 4 and fully exposing the inside of the equipment. This makes it convenient for staff to carry out comprehensive maintenance and repair work on all internal components of the equipment, including each testing station and the limiting assembly. This avoids the need to use tools to disassemble the bolts one by one, effectively reducing the workload of the staff and improving the maintenance and repair efficiency of the main body 18 of the phase light detection equipment.
[0036] Structural Description: The main body 18 of the phase light detection equipment serves as the core frame of the entire equipment and forms the basis for the installation of other components. Limiting components are installed on both sides of the frame. The short-side detection station 1 is installed inside the left side of the frame, the long-side detection station 3 is installed inside the right side, and the front and back detection station 2 is installed inside the middle, each used to perform different detection functions. The cabinet door 6 of the short-side detection station is installed on the outer wall of the left side of the frame, the cabinet door 8 of the long-side detection station is installed on the outer wall of the right side, and the cabinet door 7 of the front and back detection station is installed on the outer wall of the middle, facilitating the maintenance and operation of each detection station. Four casters 5 are installed at the lower end of the frame to facilitate the overall movement of the equipment.
[0037] Short side inspection station 1: Installed inside the left side of the frame of the phase light inspection equipment 18, it is used to inspect the short side of the glass. The cabinet door 6 of the short side inspection station is used in conjunction with it to open and close the equipment in the station and to perform daily maintenance and repair.
[0038] Front and back inspection station 2: Installed inside the frame of the main body 18 of the phase light inspection equipment, it is responsible for inspecting the front and back of the glass. The cabinet door 7 of the front and back inspection station works in conjunction with the station to realize the operation and maintenance of the equipment inside the station.
[0039] Long side inspection station 3: Installed inside the right side of the frame of the phase light inspection equipment 18, it is responsible for the inspection of the long side of the glass. The cabinet door 8 of the long side inspection station provides the operation and maintenance entrance for this station.
[0040] 5. There are four casters in total. They are installed at the lower end of the frame of the main body 18 of the phase light detection equipment, so that the equipment can be moved flexibly in the work site and the position of the equipment can be adjusted to adapt to different working environments and detection needs.
[0041] Protective side plate 4: The outer wall of the lower fixed rod is rotatably connected to the inside of the upper groove of the fixed seat 13, and the outer wall is slidably connected to the inside of one side of the frame of the phase light detection equipment body 18. The outer wall of the upper protrusion is slidably connected to the inside of the lower groove of the protrusion plate 12. Two T-shaped block slots 11 are opened on the upper outer wall of the protective side plate 4, and the second limiting block slots 17 are opened on the outer walls on both sides of the upper protrusion. The position can be adjusted and fixed by sliding and rotating, which plays a protective and limiting role in the glass detection process.
[0042] The convex plate 12 is fixedly installed on the upper outer wall of one side of the frame of the main body 18 of the phase light detection equipment. The two outer walls are rotatably connected to the rotating threaded rod sleeve 10. The lower end groove cooperates with the upper end protrusion of the protective side plate 4 to slide, providing an installation and sliding track for the protective side plate 4. At the same time, the protective side plate 4 is fixed by rotating threaded rod sleeve 10 and other structures.
[0043] Fixed seat 13: It is fixedly installed on the outer wall of one side of the frame of the phase light detection equipment body 18. Its groove is rotatably connected to the fixed rod at the lower end of the protective side plate 4, providing a fulcrum for rotation of the protective side plate 4 and ensuring that the protective side plate 4 can rotate flexibly.
[0044] H-type limiting block 9: Both ends are respectively engaged with the H-type block groove formed by the T-type block groove 11 on the frame of the corresponding protective side plate 4 and the phase light detection equipment body 18, which is used to further fix the position of the protective side plate 4, enhance the stability of the protective side plate 4, and prevent it from shifting during the detection process.
[0045] Rotating threaded rod sleeve 10: Rotatably connected to the outer walls of both sides of the convex plate 12, with one end near the convex plate 12 extending rotatably into the first limiting block groove 16, and internally threadedly connected to the rotating threaded rod 15, thereby driving the limiting block 14 through rotation;
[0046] Limiting block 14: It slides inside the first limiting block groove 16, one end is rotatably connected to the rotating threaded rod 15, and the other end slides to the lower end of the protrusion 12 and is slidably connected to the second limiting block groove 17. By moving, it can limit and fix the protective side plate 4.
[0047] Rotating threaded rod 15: One end is rotatably connected to the outer wall of the limiting block 14, and the other end is threadedly connected to the inside of the rotating threaded rod sleeve 10. Under the rotation of the rotating threaded rod sleeve 10, it drives the limiting block 14 to move, thereby fixing and loosening the protective side plate 4.
[0048] The embodiments of the present utility model have been described in detail above with reference to the accompanying drawings. However, the present utility model is not limited to the above embodiments. Within the scope of knowledge possessed by those skilled in the art, various changes can be made without departing from the spirit of the present utility model.
Claims
1. A multi-station displacement-type glass phase light detection device, comprising a short-side detection station (1), a front and back detection station (2), a long-side detection station (3), and a phase light detection device body (18), characterized in that: Limiting components are provided on both sides of the main body (18) of the phase light detection device; The limiting assembly includes a protective side plate (4), a protruding plate (12), a fixed seat (13), and two H-shaped limiting blocks (9). The fixed seat (13) is fixedly installed on the outer wall of one side of the frame of the phase light detection equipment body (18). The outer wall of the lower end of the protective side plate (4) is rotatably connected to the upper groove of the fixed seat (13). The protruding plate (12) is fixedly installed on the upper outer wall of one side of the frame of the phase light detection equipment body (18). T-shaped block slots (11) are opened on the outer walls of the two protruding blocks on both ends of the frame of the phase light detection equipment body (18). The upper outer wall of the protective side plate (4) is opened with the same two T-shaped block slots (11). Rotary threaded rod sleeves (10) are rotatably connected to the outer walls of both sides of the protruding plate (12). Among them, the two ends of the two H-shaped limiting blocks (9) are respectively engaged with the T-shaped block slots (11) on the corresponding protective side plate (4) and the main body (18) frame of the phase light detection equipment to form H-shaped block slots. The outer walls of the upper end of the protective side plate (4) are provided with second limiting block slots (17), and the inner walls of the lower end of the convex plate (12) are provided with first limiting block slots (16). The two first limiting block slots (16) are slidably connected with limiting blocks (14). The two first limiting block slots (16) are provided with rotating threaded rods (15). The two limiting components are respectively set on both sides of the main body (18) frame of the phase light detection equipment.
2. The multi-workstation displacement-type glass phase light detection device according to claim 1, characterized in that: The outer wall of the protective side plate (4) is slidably connected to the inner side of the frame of the main body (18) of the phase light detection equipment, and the outer wall of the upper protrusion of the protective side plate (4) is slidably connected to the inner side of the groove at the lower end of the protrusion plate (12). Among them, the two T-shaped block slots (11) on the protective side plate (4) are respectively used in conjunction with the T-shaped block slots (11) on the frame of the corresponding phase light detection equipment body (18).
3. The multi-workstation displacement-type glass phase light detection device according to claim 1, characterized in that: The two rotating threaded rod sleeves (10) extend into the interior of the first limiting block groove (16) at the end near the convex plate (12), and the two rotating threaded rods (15) are rotatably connected to the outer wall of the corresponding limiting block (14) at the end near the limiting block (14). Among them, the ends of the two limiting blocks (14) near the second limiting block groove (17) are slidably extended to the lower end of the convex plate (12) and are slidably connected to the interior of the corresponding second limiting block groove (17) respectively. The ends of the two rotating threaded rods (15) away from the limiting blocks (14) are respectively connected to the interior threads of the corresponding rotating threaded rod sleeve (10).
4. The multi-workstation displacement-type glass phase light detection device according to claim 1, characterized in that: The short-side detection station (1) is installed inside the left side of the frame of the main body (18) of the phase light detection equipment; Among them, the long side detection station (3) is installed inside the right side of the main body (18) frame of the phase light detection equipment, and the front and back detection station (2) is installed inside the middle of the main body (18) frame of the phase light detection equipment.
5. The multi-workstation displacement-type glass phase light detection device according to claim 1, characterized in that: The phase light detection equipment body (18) has a short-side detection station cabinet door (6) installed on the outer left side of the frame. Among them, the short side detection station cabinet door (6) is used in conjunction with the short side detection station (1), and the long side detection station cabinet door (8) is installed on the outer right side of the frame of the phase light detection equipment (18).
6. The multi-workstation displacement-type glass phase light detection device according to claim 5, characterized in that: The long-side detection station cabinet door (8) is used in conjunction with the long-side detection station (3). The front and back detection station cabinet doors (7) are installed on the outer wall of the frame of the phase light detection equipment body (18). Among them, the front and back inspection station cabinet door (7) is used in conjunction with the front and back inspection station (2), and four casters (5) are installed at the lower end of the frame of the phase light inspection equipment body (18).