CN115301410B - Electric dust-removing cathode and anode measuring deviation-adjusting instrument - Google Patents

Abstract

The application discloses an electric precipitation cathode and anode measurement polarization adjustment instrument, which has a simple structure, solves the problems of narrow adjustment space position and high measurement and adjustment work difficulty of an electric precipitator in the electric precipitation cathode and anode measurement polarization adjustment instrument to a certain extent, and skillfully combines the matching action of a cam groove and a connecting rod, so that the device has the polarization adjustment function while automatically placing measurement and sensing, and can realize complete automatic polarization adjustment measurement by adopting a mechanical part and a motor, thereby greatly saving the working time and increasing the working efficiency.

Description

Electric dust-removing cathode and anode measuring deviation-adjusting instrument

Technical Field

The application relates to the field of flue gas purification, in particular to an electric precipitation cathode and anode measurement deviation adjusting device.

Background

The electric dust remover ionizes gas by utilizing direct current negative high voltage, generates corona discharge, charges dust, separates dust from gas under the action of strong electric field force, and the direct current negative high voltage is connected into a cathode system through a high-voltage isolating switch cabinet, and the cathode system is suspended in the middle of an anode plate by virtue of a hanging device, and is insulated from a supporting steel beam by adopting a porcelain insulator and an insulating plate. The cathode is fixed on the cathode frame by vibration and is also provided with high-voltage direct-current negative electricity, and is insulated with an external transmission device by means of a porcelain shaft and an insulating plate. The anode is directly hung on a precipitation beam connected with the dust remover body and is reliably grounded together with the dust remover shell. The cathode and anode electrode spacing is strictly required, when high voltage is introduced into the electric field operation process and high voltage direct current is input to reach a certain voltage demarcation point, the electric dust removing cathode can instantly generate sparks, the cathode and anode electrode spacing breaks down, and the electric discharge sound and spark splash with huge sound are accompanied, and the electric dust removing cathode is equivalent to the connection of the cathode and the anode electrode, so that the anode plate burns through. The control picture of the upper computer of the electric dust collector can see that the secondary voltage and secondary current drop instantaneously, the local meter swings frequently, the cremation rate displays figures, the general spark discharge can limit the voltage and current parameters within a certain range, and if serious, the electric field is directly caused to be backed up. In electric dust removal maintenance, strict requirements are placed on the distance between a charged body cathode and a dust collection anode, for example: an electric dust collector matched with a 300MW thermal power generating unit is provided with 2 dust collectors, 4 to 5 electric fields are formed, the height is 16.6 meters, the depth is 4 meters, and the number of channels of a cathode and an anode is 450. Each channel spacing is only about 175 mm. On the working surface with the height of 16.6 meters facing such many narrow channels, the workload is huge by measuring and adjusting one by one, and the measuring is inconvenient by using a tape measure or a steel plate rule.

Disclosure of Invention

This section is intended to outline some aspects of embodiments of the application and to briefly introduce some preferred embodiments. Some simplifications or omissions may be made in this section as well as in the description of the application and in the title of the application, which may not be used to limit the scope of the application.

The application is provided in view of the problems of narrow adjustment space position and great measurement adjustment work difficulty of the electric dust collector in the existing electric dust collector cathode and anode measurement polarization analyzer.

Therefore, the application aims to provide an electric precipitation cathode-anode measurement polarization analyzer.

In order to solve the technical problems, the application provides the following technical scheme: the fixing assembly comprises a supporting frame, a transverse connecting plate arranged above the supporting frame and a limit cover plate arranged at the upper end of the transverse connecting plate; the movable assembly comprises a driving gear arranged at the upper end of the transverse connecting plate, a limit sleeve connected to the side part of the driving gear, a lifting component arranged at the upper end of the transverse connecting plate, a sensor arranged above the lifting component, a lifting connecting rod connected to one end of the lifting component far away from the limit sleeve, and a driving motor arranged on the transverse connecting plate and connected with the driving gear; and the deflection adjusting assembly comprises a driven gear arranged on the transverse connecting plate, a turnover part connected to the side part of the driven gear and an adjusting motor arranged on the turnover part.

As a preferable scheme of the electric precipitation cathode and anode measurement polarization analyzer, the application comprises the following steps: the horizontal board that links includes the first fixed plate of being connected with the support frame is vertical and the second fixed plate of placing with first fixed plate level, be equipped with in the middle of the first fixed plate with drive gear complex fixed rack, be equipped with in the middle of the second fixed plate with driven gear complex removal rack, drive gear passes through the mouth groove and links to each other with driving motor.

As a preferable scheme of the electric precipitation cathode and anode measurement polarization analyzer, the application comprises the following steps: the driving gear comprises a belt pulley arranged at the lower end of the transverse connecting plate and a driving shaft coaxially arranged at the center of the driving gear.

As a preferable scheme of the electric precipitation cathode and anode measurement polarization analyzer, the application comprises the following steps: the limiting cover plate is provided with a sliding groove at one end far away from the transverse connecting plate, and the limiting sleeve and the overturning sleeve are connected with the driving shaft through the sliding groove.

As a preferable scheme of the electric precipitation cathode and anode measurement polarization analyzer, the application comprises the following steps: the utility model discloses a lifting device for the electric motor car, including the sleeve, spacing sleeve, sliding tray, vertical setting, lift sleeve, the spacing sleeve one end is provided with the lantern ring with the coaxial complex of drive shaft, and the axial setting is in the lantern ring lateral part and with sliding tray complex sliding plate and vertical setting is kept away from the lift sleeve of lantern ring one end at the sliding plate, lift sleeve lateral part is equipped with the lifting tray.

As a preferable scheme of the electric precipitation cathode and anode measurement polarization analyzer, the application comprises the following steps: the lifting part comprises a lifting shaft and a lifting rod, wherein the lifting shaft is coaxially connected to one end of the driving shaft far away from the gear, the lifting rod is arranged at the center of the lifting sleeve, a first cam groove is formed in the side part of the lifting shaft, the lifting rod comprises a transverse connecting rod matched with the first cam groove and the lifting groove and a vertical connecting rod coaxially arranged in the lifting sleeve, and the sensor is arranged at the top of the vertical connecting rod.

As a preferable scheme of the electric precipitation cathode and anode measurement polarization analyzer, the application comprises the following steps: the lifting connecting rod center is equipped with perpendicular connecting rod complex first lifting ring and sets up at lifting connecting rod both ends and upset part complex second lifting ring, the lifting ring sets up respectively at perpendicular connecting rod top and upset part top.

As a preferable scheme of the electric precipitation cathode and anode measurement polarization analyzer, the application comprises the following steps: the turnover part comprises a driven disc, a turnover sleeve and a turnover rod, wherein the driven disc is arranged at the upper end of the second fixed plate and is coaxially connected with the driven gear, the turnover sleeve is arranged at the side part of the driven disc, the turnover rod is arranged at the outer side of the turnover sleeve, and a second cam groove is arranged on the surface, far away from one end of the gear, of the driven disc.

As a preferable scheme of the electric precipitation cathode and anode measurement polarization analyzer, the application comprises the following steps: the turning rod comprises a lifting sleeve rod arranged on the outer side of the turning sleeve and a deviation adjusting rod axially arranged on the side part of the lifting sleeve rod and far away from one end of the second fixing plate, a central hole matched with the turning sleeve is formed in the center of the lifting sleeve rod, and a table buckle is axially arranged inside the lifting sleeve rod.

As a preferable scheme of the electric precipitation cathode and anode measurement polarization analyzer, the application comprises the following steps: the turnover sleeve is axially provided with a turnover connecting rod matched with the second cam groove, and the side part of the turnover sleeve is provided with a lifting opening groove matched with the lifting sleeve rod table.

The application has the beneficial effects that: the application has simple structure, solves the problems of narrow adjustment space position and great measurement and adjustment work difficulty of the electric dust collector of the cathode and anode measurement polarization analyzer to a certain extent, and skillfully combines the matching action of the cam groove and the connecting rod, so that the device has the polarization adjusting function while being automatically placed into the measurement sensor, and can realize complete automatic polarization adjustment measurement by adopting a mechanical part and a motor, thereby greatly saving the working time and increasing the working efficiency.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are needed in the description of the embodiments will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present application, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art. Wherein:

fig. 1 is a schematic diagram of the overall structure of the cathode-anode measurement polarization-adjustment instrument for electric precipitation.

Fig. 2 is a schematic diagram of the overall installation structure of the cathode and anode measurement polarization analyzer for electric precipitation according to the present application.

Fig. 3 is a schematic diagram of the moving parts of the cathode and anode measurement polarization analyzer for electric precipitation according to the present application.

Fig. 4 is a schematic diagram of an explosion structure of a moving part of the cathode and anode measurement polarization analyzer for electric precipitation according to the present application.

Fig. 5 is a schematic diagram of the linkage structure of the moving part and the turning part of the cathode and anode measurement polarization analyzer for electric precipitation according to the present application.

Fig. 6 is a schematic structural diagram of a deflection regulating component of the cathode and anode measurement deflection regulating device for electric precipitation according to the present application.

Fig. 7 is a schematic structural diagram of a turnover part of the cathode and anode measurement polarization analyzer for electric precipitation according to the present application.

Detailed Description

In order that the above-recited objects, features and advantages of the present application will become more readily apparent, a more particular description of the application will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present application, but the present application may be practiced in other ways other than those described herein, and persons skilled in the art will readily appreciate that the present application is not limited to the specific embodiments disclosed below.

Further, reference herein to "one embodiment" or "an embodiment" means that a particular feature, structure, or characteristic can be included in at least one implementation of the application. The appearances of the phrase "in one embodiment" in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments.

Further, in describing the embodiments of the present application in detail, the cross-sectional view of the device structure is not partially enlarged to a general scale for convenience of description, and the schematic is only an example, which should not limit the scope of protection of the present application. In addition, the three-dimensional dimensions of length, width and depth should be included in actual fabrication.

Example 1

Referring to fig. 1-4, an overall structure schematic diagram of an electric dust removal cathode and anode measurement polarization analyzer is provided, which comprises a fixing assembly 100, a supporting frame 101, a transverse connection plate 102, a limit cover plate 103, a support frame 101, a cathode and anode electric box frame box, a transverse connection plate 102, a limit cover plate 103 and a support frame, wherein the support frame 101 is connected with the cathode and anode electric box frame box, the transverse connection plate 102 is arranged above the support frame 101, the transverse connection plate 102 is arranged below the cathode and anode electric box and is perpendicular to the cathode and anode plane, and the limit cover plate 103 is arranged at the upper end of the transverse connection plate 102; the moving assembly 200 comprises a driving gear 201 arranged at the upper end of the transverse connecting plate 102, a limit sleeve 202 connected to the side part of the driving gear 201, a lantern ring 202a matched with a driving shaft 201b is arranged at one end of the limit sleeve 202, a sliding plate 202b axially arranged at the side part of the lantern ring 202a and matched with the sliding groove 103a, and a lifting sleeve 202c vertically arranged at one end of the sliding plate 202b far away from the lantern ring 202a, a lifting groove 202d is arranged at the side part of the lifting sleeve 202c, a lifting part 203 is arranged at the upper end of the transverse connecting plate 102, the lifting part 203 comprises a lifting shaft 203a coaxially connected to one end of the driving shaft 201b far away from the gear and a lifting rod 203b arranged in the center of the lifting sleeve 202c, a first cam groove 203c is arranged at the side part of the lifting shaft 203a, the lifting rod 203b comprises a transverse connecting rod 203b-1 matched with the first 203c and the lifting groove 202d and a vertical connecting rod 203b-2 coaxially arranged in the sleeve, a sensor 204 is arranged at the top of the vertical connecting rod 203b-2, a sensor 204 arranged above the lifting part 203 and a lifting part 205 connected to the lifting part 205b at the upper end far away from the gear, a lifting part 205b is arranged at the top of the lifting part 205b and a second lifting part 205b is arranged at the center of the lifting part 205b and is matched with the lifting rod 2; and, the offset adjusting assembly 300, including setting up the driven gear 301 on the horizontal link plate 102, connect the upset sleeve 304 of word driven gear 301 lateral part, set up the inside upset part of upset sleeve 304, upset part includes setting up the driven plate 302a of second fixed plate 102b upper end and driven gear 301 coaxial coupling, set up the upset sleeve 304 and setting up the upset pole 302c in upset sleeve 304 in driven plate 302a lateral part, the drive plate is kept away from gear one end surface and is equipped with second cam groove 302b, and set up the adjusting assembly on the upset assembly.

Specifically, the transverse connection plate 102 includes a first fixing plate 102a vertically connected with the support frame 101 and a second fixing plate 102b horizontally placed with the first fixing plate 102a, a fixing rack 102c matched with the driving gear 201 is arranged in the middle of the first fixing plate 102a, a second rack matched with the driven gear 301 is arranged in the middle of the second fixing plate 102b, the driving gear 201 and the driven gear 301 include a belt pulley 201a arranged at the lower end of the transverse connection plate 102 and a driving shaft 201b coaxially arranged at the centers of the driving gear 201 and the driven gear 301, and a through hole matched with the lifting rod 203b is arranged at the center of the limiting sleeve 202.

Preferably, the sensor 204 in the device adopts a sw-m50 laser range finder, and the measurement accuracy is-1.5 mm to +1.5mm.

The operation process comprises the following steps: when an operator uses the electric precipitation cathode-anode measurement polarization-adjusting device to adjust the cathode of the dust collector, the operator firstly places the support frame 101 above the electric dust collector support to be fixed, then the operator opens the switch of the driving motor 206, at the moment, the driving motor 206 drives the belt to rotate, the belt pulley 201a drives the driving gear 201 to rotate, the driving shaft 201b coaxially connected with the driving gear 201 drives the lifting shaft 203a to rotate together, the transverse connecting rod 203b-1 drives the vertical connecting rod 203b-2 to move up and down along the lifting sleeve 202c under the cooperation of the first cam groove 203c and the transverse connecting rod 203b-1, at the moment, under the connection effect of the lifting connecting rod 205, the vertical connecting rod 203b-2 drives the overturning part to move up and down, so that the vertical movement between the cathode-anode plates of the electric dust collector can be realized, the automatic feeding and taking-out of the polarization-adjusting component 300 and the sensor 204 are realized, and the working time is greatly saved.

Example 2

Referring to fig. 4 to 7, this embodiment differs from the first embodiment in that: the fixed assembly 100 comprises a support frame 101, a transverse connection plate 102 arranged above the support frame 101, wherein the transverse connection plate 102 comprises a first fixed plate 102a vertically connected with the support frame 101 and a second fixed plate 102b horizontally arranged with the first fixed plate 102a, a second cam groove 302b is arranged in the middle of the second fixed plate 102b and is connected with an adjusting motor 303, the moving rack 102d can horizontally slide in the center of the second fixed plate 102b, the offset assembly 300 comprises a driven gear 301 arranged on the second fixed plate 102b, the driven gear 301 is meshed with the moving rack 102d, a side overturning part connected with the driven gear 301 is arranged on the side part of the driven gear 301, the overturning part comprises a driven disc 302a coaxially connected with the driven gear 301 at the upper end of the second fixed plate 102b, an overturning sleeve 304 arranged on the side part of the driven disc 302a and an overturning rod 302c arranged on the outer side of the overturning sleeve 304, the driven disc 302a is provided with a second cam groove 302b far away from one end surface of the gear, the overturning sleeve 302c comprises a lifting sleeve 302c-1 arranged on the outer side of the overturning sleeve 304 and a lifting sleeve 302c-1 arranged on the side of the overturning sleeve 302b, the axial offset sleeve 302c is matched with the second cam groove 302 b-b, and the overturning sleeve 302c is arranged on the side part of the overturning sleeve 302b and the overturning sleeve 302b is axially matched with the overturning sleeve 302c, and the overturning sleeve 302b is arranged on the side part of the overturning sleeve 302b, and the overturning sleeve 302 b.

The rest of the structure is the same as in embodiment 1.

The operation process comprises the following steps: when an operator uses the electric dust removal cathode-anode measurement polarization-adjusting device to conduct cathode-anode polarization adjustment of the electric dust removal, the operator firstly fixes the support frame 101 on the electric dust removal fixing frame, then the operator turns on the driving motor 206, the moving assembly 200 drives the driving gear 201 to move under the driving of the adjusting motor 303, the driving gear 201 drives the lifting shaft 203a to rotate under the cooperation of the fixing rack 102c, at the moment, under the cooperation of the first cam groove 203c on the lifting shaft 203a and the transverse connecting rod 203b-1, the transverse connecting rod 203b-1 drives the vertical connecting rod 203b-2 and the sensor 204 to move up and down along the inside of the lifting sleeve 202c, the transverse connecting rod 203b-1 drives the lifting connecting rod 205 and the lifting sleeve rod 302c-1 to move up and down, when the sensor 204 moves to a proper position, the distance between cathode and anode plates is measured, and the driving motor 206 is disconnected with the driving gear 201 at the moment, the movable rack 102d is meshed with the driven gear 301, the adjusting motor 303 drives the movable rack 102d to move left and right on the second transverse connecting plate 102, under the cooperation of the movable rack 102d and the driven gear 301, the driven gear 301 drives the driven disc 302a to rotate, under the cooperation of the second cam groove 302b on the driven disc 302a and the turning connecting rod 304a, the turning connecting rod 304a drives the turning sleeve 304 to rotate at a certain angle, under the cooperation of the lifting opening groove on the side part of the turning sleeve 304 and the lifting sleeve rod 302c-1, the lifting sleeve rod 302c-1 realizes the swinging at a certain angle, when the lifting sleeve rod 302c-1 adjusts the negative plate to a proper position, the sensor 204 receives a signal, at the moment, the movable rack 102d moves away from the cooperation with the driven gear 301, and the driving motor 206 is matched with the belt again to drive the driving gear 201 to move to the next group of polar plates.

It is important to note that the construction and arrangement of the application as shown in the various exemplary embodiments is illustrative only. Although only a few embodiments have been described in detail in this disclosure, those skilled in the art who review this disclosure will readily appreciate that many modifications are possible (e.g., variations in sizes, dimensions, structures, shapes and proportions of the various elements, values of parameters (e.g., temperature, pressure, etc.), mounting arrangements, use of materials, colors, orientations, etc.) without materially departing from the novel teachings and advantages of the subject matter described in this application. For example, elements shown as integrally formed may be constructed of multiple parts or elements, the position of elements may be reversed or otherwise varied, and the nature or number of discrete elements or positions may be altered or varied. Accordingly, all such modifications are intended to be included within the scope of present application. The order or sequence of any process or method steps may be varied or re-sequenced according to alternative embodiments. In the claims, any means-plus-function clause is intended to cover the structures described herein as performing the recited function and not only structural equivalents but also equivalent structures. Other substitutions, modifications, changes and omissions may be made in the design, operating conditions and arrangement of the exemplary embodiments without departing from the scope of the present applications. Therefore, the application is not limited to the specific embodiments, but extends to various modifications that nevertheless fall within the scope of the appended claims.

Furthermore, in an effort to provide a concise description of the exemplary embodiments, all features of an actual implementation may not be described (i.e., those not associated with the best mode presently contemplated for carrying out the application, or those not associated with practicing the application).

It should be appreciated that in the development of any such actual implementation, as in any engineering or design project, numerous implementation-specific decisions may be made. Such a development effort might be complex and time consuming, but would nevertheless be a routine undertaking of design, fabrication, and manufacture for those of ordinary skill having the benefit of this disclosure.

It should be noted that the above embodiments are only for illustrating the technical solution of the present application and not for limiting the same, and although the present application has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that the technical solution of the present application may be modified or substituted without departing from the spirit and scope of the technical solution of the present application, which is intended to be covered in the scope of the claims of the present application.

Claims (5)

1. The utility model provides an electric precipitation negative pole measurement analyzer which characterized in that: comprising the steps of (a) a step of,

the fixing assembly (100) comprises a supporting frame (101), a transverse connecting plate (102) arranged above the supporting frame (101) and a limit cover plate (103) arranged at the upper end of the transverse connecting plate (102);

the moving assembly (200) comprises a driving gear (201) arranged at the upper end of the transverse connection plate (102), a limit sleeve (202) connected to the side part of the driving gear (201), a lifting component (203) arranged at the upper end of the transverse connection plate (102), a sensor (204) arranged above the lifting component (203), a lifting connecting rod (205) connected to one end, far away from the limit sleeve (202), of the lifting component (203), and a driving motor (206) arranged on the transverse connection plate (102) and connected with the driving gear (201); the method comprises the steps of,

the deflection adjusting component (300) comprises a driven gear (301) arranged on the transverse connecting plate (102), a turnover part connected with the side part of the driven gear (301), an adjusting motor (303) arranged on the turnover part and a turnover sleeve (304) connected with the side part of the driven gear (301),

the transverse connection plate (102) comprises a first fixed plate (102 a) vertically connected with the support frame (101) and a second fixed plate (102 b) horizontally arranged with the first fixed plate (102 a), a fixed rack (102 c) matched with the driving gear (201) is arranged in the middle of the first fixed plate (102 a), a movable rack (102 d) matched with the driven gear (301) is arranged in the middle of the second fixed plate (102 b), the driving gear (201) is connected with the driving motor (206) through a slot,

the driving gear (201) comprises a belt pulley (201 a) arranged at the lower end of the transverse connection plate (102) and a driving shaft (201 b) coaxially arranged at the center of the driving gear (201),

one end of the limit cover plate (103) far away from the transverse connecting plate (102) is provided with a sliding groove (103 a), the limit sleeve (202) and the turnover sleeve (304) are connected with a driving shaft (201 b) through the sliding groove (103 a),

one end of the limit sleeve (202) is provided with a collar (202 a) matched with the driving shaft (201 b), a sliding plate (202 b) axially arranged on the side part of the collar (202 a) and matched with the sliding groove (103 a) and a lifting sleeve (202 c) vertically arranged on one end of the sliding plate (202 b) far away from the collar (202 a), the side part of the lifting sleeve (202 c) is provided with a lifting groove (202 d),

the lifting component (203) comprises a lifting shaft (203 a) and a lifting rod (203 b), wherein the lifting shaft (203 a) is coaxially connected to the driving shaft (201 b) and is far away from one end of the collar (202 a), the lifting rod (203 b) is arranged in the center of the lifting sleeve (202 c), a first cam groove (203 c) is formed in the side portion of the lifting shaft (203 a), a transverse connecting rod (203 b-1) matched with the first cam groove (203 c) and the lifting groove (202 d) and a vertical connecting rod (203 b-2) are coaxially arranged in the lifting sleeve (202 c), and the sensor (204) is arranged at the top of the vertical connecting rod (203 b-2).

2. The electric precipitation cathode-anode measurement analyzer as claimed in claim 1, wherein: the lifting connecting rod (205) is characterized in that a first lifting ring (205 a) matched with the vertical connecting rod (203 b-2) and a second lifting ring (205 b) matched with the overturning part are arranged at the center of the lifting connecting rod (205), and the first lifting ring (205 a) and the second lifting ring (205 b) are respectively arranged at the top of the vertical connecting rod (203 b-2) and the top of the overturning part.

3. The electric precipitation cathode-anode measurement analyzer as claimed in claim 2, wherein: the turnover part comprises a driven disc (302 a) arranged at the upper end of the second fixed plate (102 b) and coaxially connected with the driven gear (301), a turnover sleeve (304) arranged on the side part of the driven disc (302 a) and a turnover rod (302 c) arranged on the outer side of the turnover sleeve (304), and a second cam groove (302 b) is arranged on the surface, far away from one end of the gear, of the driven disc (302 a).

4. The electric precipitation cathode and anode measurement analyzer as claimed in claim 3, wherein: the turnover rod (302 c) comprises a lifting sleeve rod (302 c-1) arranged on the outer side of the turnover sleeve (304) and a deflection adjusting rod (302 c-2) axially arranged on the side part of the lifting sleeve rod (302 c-1) and far away from one end of the second fixing plate (102 b), a central hole matched with the turnover sleeve (304) is formed in the center of the lifting sleeve rod (302 c-1), and a table buckle is axially arranged inside the lifting sleeve rod (302 c-1).

5. The electric precipitation cathode-anode measurement analyzer as claimed in claim 1, wherein: the turnover sleeve (304) is axially provided with a turnover connecting rod (304 a) matched with the second cam groove (302 b), and the side part of the turnover sleeve (304) is provided with a lifting opening groove matched with the lifting sleeve rod (302 c-1) in a table buckle mode.