CN117001881A - Granule water separator of large-yield granule cutting system - Google Patents

Abstract

The application relates to a granule water separation device of a large-yield granule cutting system, which relates to the field of granule cutting system separation devices, and comprises a housing, wherein a feed inlet is formed in the housing, a filtering mechanism is arranged in the housing, the filtering mechanism is arranged along the water flow direction, the filtering mechanism is connected with the housing through a supporting mechanism, a water flow guiding mechanism is arranged on the supporting mechanism, and the water flow guiding mechanism is used for guiding water and particles to flow towards the filtering mechanism. The application has the effect of effectively avoiding the retention of particles on the filtering mechanism, thereby improving the dehydration efficiency of the particles.

Description

Granule water separator of large-yield granule cutting system

Technical Field

The application relates to the field of a separating device of a granulating system, in particular to a granule water separating device of a high-yield granulating system.

Background

The underwater pelletizing system is one special pelletizing mode for hot cutting mold surface, and may be used in cutting various kinds of material, including hot melt glue, thermoplastic rubber, polyester material, nylon and other hot melt plastic. The method is particularly suitable for processing TPE, TPU, PA, PET, ABS, PP, PVC, waxy materials, colloid materials, glass filling materials, carbon fibers, filling modified materials and the like, and when particles are collected, the particles are required to be separated from water.

At present, the domestic underwater pelletizing system is provided with a pellet water separator, is commonly applied to a small underwater pelletizing system, has a simple structure, is generally only provided with a screen arranged in a water flow channel, has a simple structure, has low particle discharge speed, and is used in a large-yield underwater pelletizing system, a large amount of particles are retained on the screen to influence the dewatering capacity of the device.

Disclosure of Invention

In order to solve the problem that the particles retained on the screen reduce the particle dehydration efficiency, the application provides a particle water separation device of a large-yield particle cutting system.

The application provides a granule water separation device of a large-yield granule cutting system, which adopts the following technical scheme:

the utility model provides a big output grain system grain water separator, includes the housing, be equipped with the feed inlet on the housing, be equipped with filtering mechanism in the housing, filtering mechanism arranges along the water flow direction, filtering mechanism with the housing passes through supporting mechanism to be connected, the last rivers guiding mechanism that is equipped with of supporting mechanism, rivers guiding mechanism is used for guiding water and granule to flow towards filtering mechanism.

Through adopting above-mentioned technical scheme, when separating particle and water, fix filtering mechanism and rivers guiding mechanism in the housing through supporting mechanism earlier, then particle and water get into in the housing from the feed inlet, particle and water impact filtering mechanism under rivers guiding mechanism's guide, realize the particle separation of water, effectively avoid the particle to detain on filtering mechanism through the impact of rivers to improve the dehydration efficiency of particle.

In a specific implementation, the supporting mechanism comprises a supporting rod arranged in the housing, a supporting plate is arranged on the supporting rod, and a supporting ring piece is arranged on the supporting plate;

the filter mechanism comprises a plurality of annular straight screens, the annular straight screens are arranged along the water flow direction, the support ring piece is inserted into two adjacent annular straight screens, and the two adjacent annular straight screens are in interference with the support plate.

Through adopting above-mentioned technical scheme, when installing the straight screen cloth of annular, insert in two adjacent annular straight screen cloth with the support ring piece to make the straight screen cloth butt of annular in the backup pad, then be connected with the housing through backup pad, bracing piece, thereby realize the installation of the straight screen cloth of annular in the housing, realize the separation of grain water through the straight screen cloth of annular, can increase filter area through increasing the quantity of the straight screen cloth of annular simultaneously, when improving the filter effect, reduced the space occupation of the straight screen cloth of annular.

In a specific implementation manner, the supporting rod penetrates through the supporting plate, two fixing rings are sleeved on the supporting rod, the supporting plate is located between the two fixing rings, each fixing ring is provided with a notch, each fixing ring is provided with a fixing screw, and the fixing screws are inserted into the fixing rings on two sides of each notch and are in threaded connection with the fixing rings.

Through adopting above-mentioned technical scheme, when backup pad and bracing piece connection installation, establish a solid fixed ring cover on the bracing piece earlier, then pass the backup pad with the bracing piece, establish another one solid fixed ring cover on the bracing piece afterwards, then screw set screw makes solid fixed ring and bracing piece fixed, and two solid fixed rings extrusion backup pads accomplish the installation of backup pad and bracing piece.

In a specific embodiment, the water flow guiding mechanism comprises a supporting cylinder arranged in the annular screen and a side wall guiding cap, a flow channel is formed between the supporting cylinder and the annular straight screen, the side wall guiding cap is circumferentially arranged along the supporting cylinder, and the distance between the side wall guiding cap and the annular straight screen is gradually increased from one side of the side wall guiding cap, which is close to the feed inlet, to one side of the side wall guiding cap, which is far away from the feed inlet.

Through adopting above-mentioned technical scheme, when water and particle from the feed inlet inflow, water and particle circulate along flow channel to under the direction of lateral wall direction cap, make water and particle flow towards annular straight screen cloth, and impact annular straight screen cloth, in the water passed through annular straight screen cloth entering housing, the particle continues to flow along flow channel, thereby realize the separation of particle water, and through setting up the lateral wall direction cap of different quantity on the support section of thick bamboo, can adjust the filtration efficiency of particle water separator, thereby adapt to the particle water separation requirement of different output, different flow's pelleter.

In a specific embodiment, the water flow guiding mechanism further comprises a top guiding cap, the inclination angle of the top guiding cap is the same as that of the side wall guiding cap, the top guiding cap is located between the feeding hole and the supporting cylinder, and a material bearing table is arranged on the top guiding cap.

Through adopting above-mentioned technical scheme, when water and particle flow from the feed inlet, rivers impact top direction cap and along top direction cap towards annular straight screen cloth flow, hold the material platform and produce the resistance to water flow, reduce the flow velocity of rivers, increase the contact time of granule water and annular straight screen cloth, improve the granule separation of water effect.

In a specific embodiment, the filter mechanism further comprises a reducing screen into which the support ring sheet is inserted, the diameter of the reducing screen gradually decreasing from a side closer to the feed inlet toward a side farther from the feed inlet.

Through adopting above-mentioned technical scheme, water and particle pass through the reducing screen in the in-process that falls, because reducing screen slope sets up, water and particle can slide along the reducing screen, increase the screening time of water and particle, improve the grain separation of water effect.

In a specific implementation manner, the annular straight screen is provided with an opening, two ends of the annular straight screen are bent to form folded edges, two folded edges are located on two sides of the opening, two folded edges are connected with nuts through bolts, and the folded edges are lapped on the supporting plate.

Through adopting above-mentioned technical scheme, when installing the straight screen cloth of annular, will annular earlier overlap on the support ring piece, owing to be equipped with the opening on the straight screen cloth of annular for the straight screen cloth of annular can be to both sides tensile, then aligns two hem, and is connected through bolt and nut, makes the straight screen cloth of annular contradict with the support ring piece, thereby improves the stability of the straight screen cloth installation of annular when improving the straight screen cloth installation convenience of annular.

In a specific embodiment, the annular straight screen is provided with a discharge pipe, the discharge pipe penetrates through the bottom wall of the housing, and the bottom wall of the housing is provided with a drain pipe.

By adopting the technical scheme, the separated particles are discharged from the discharge pipe, and the separated water is discharged from the drain pipe to the housing, so that the particles and the water are respectively discharged.

In a specific implementation manner, two material guiding plates which are arranged in a crossing manner are arranged on the side wall of the feeding hole, and the two material guiding plates are arranged vertically.

Through adopting above-mentioned technical scheme, through the perpendicular setting of two stock guides, the stock guide divide into four the same regions with the feed inlet to improve the homogeneity that water and particle flow to top direction cap.

In a specific implementation mode, an operation opening is formed in the cover shell, a cover plate for blocking the operation opening is arranged on the cover shell, the cover plate and the cover shell are rotatably arranged through a hinge, and the cover plate and the cover shell are fixed through a lock catch.

Through adopting above-mentioned technical scheme, when the grain separation in the housing appears unusual, through pulling the hasp for apron and housing are released fixedly, then rotate the apron and make the operation mouth open, operating personnel can handle the unusual situation through the operation mouth, improves the convenience that the unusual situation handled.

In summary, the present application includes at least one of the following beneficial technical effects:

1. when the particle water is separated, the filtering mechanism and the water flow guiding mechanism are arranged in the housing through the supporting mechanism, water and particles enter from the feed inlet, then the water and the particles flow towards the filtering mechanism under the guiding of the water flow guiding mechanism and impact the filtering mechanism, so that the particle water separation is realized, the particle retention on the filtering mechanism is effectively avoided through the impact of the water flow, and the particle dehydration efficiency is improved;

2. when the annular straight screen is installed, the supporting plates are firstly installed on the supporting rods, then two adjacent annular straight screens are sleeved on the supporting ring piece, the annular straight screens are abutted with the supporting plates, and the filtering area of the annular straight screens can be determined by the height of the filtering mechanism, so that a larger filtering area can be arranged in a smaller space, the filtering effect is improved, and meanwhile, the space occupation of the screens is reduced;

3. through setting up the lateral wall direction cap of different quantity along the vertical direction of support section of thick bamboo to/or set up the straight screen cloth of annular of different quantity, can adjust the filtration efficiency of grain water separator, thereby adapt to the grain water separation requirement of the pelleter of different output, different flow.

Drawings

FIG. 1 is a schematic diagram of a granule water separator of a high-yield granule cutting system according to an embodiment of the present application.

Fig. 2 is a schematic view for showing the internal structure of the housing.

Fig. 3 is a schematic view for showing the structure of the fixing ring.

Fig. 4 is an enlarged view of a portion B in fig. 3.

Fig. 5 is an enlarged view of a portion C in fig. 3.

Fig. 6 is an enlarged view of a portion a in fig. 1.

Reference numerals illustrate: 1. a housing; 111. an upper cover; 112. a lower cover; 12. a feed inlet; 13. a discharge pipe; 14. a drain pipe; 15. a material guide plate; 161. an operation port; 162. a cover plate; 163. a hinge; 164. locking; 2. a filtering mechanism; 21. an annular straight screen; 211. an opening; 212. folding edges; 22. reducing screen; 3. a water flow guiding mechanism; 31. a support cylinder; 32. a sidewall guide cap; 33. a top guide cap; 34. a flow channel; 35. a connecting rod; 36. a material bearing table; 37. reducing inclined plane; 4. a support mechanism; 41. a support rod; 42. a cross bar; 43. a support plate; 44. a fixing ring; 45. a notch; 46. a fixing screw; 47. and supporting the ring sheet.

Detailed Description

The application is described in further detail below with reference to fig. 1-6.

The embodiment of the application discloses a granule water separation device of a large-yield granule cutting system.

Referring to fig. 1 and 2, a granule-separating device of a high-yield granule-cutting system comprises a housing 1, wherein the housing 1 is a cylindrical housing, the housing 1 is arranged in the vertical direction, an upper sealing cover 111 is arranged at the upper port of the housing 1, the upper sealing cover 111 is connected with the housing 1 through bolts and nuts, a lower sealing cover 112 is arranged at the bottom port of the housing 1, the lower sealing cover 112 is integrally manufactured with the housing 1, a feed inlet 12 is arranged on the upper sealing cover 111, a filtering mechanism 2 is arranged in the housing 1, a water flow guiding mechanism 3 for guiding water and granules to flow towards the filtering mechanism 2 is arranged in the filtering mechanism 2, the filtering mechanism 2 and the water flow guiding mechanism 3 are both connected with the housing 1 through a supporting mechanism 4, a discharge pipe 13 for guiding the granules to be discharged out of the housing 1 is arranged on the supporting mechanism 4, the discharge pipe 13 penetrates through the lower sealing cover 112, and a drain pipe 14 is arranged on the lower sealing cover 112.

When the particle water is separated, the filter mechanism 2 and the water flow guide mechanism 3 are firstly arranged in the housing 1 through the supporting mechanism 4, then the particle water enters the housing 1 from the feeding hole 12, then the particle water is guided to flow to the filter mechanism 2 through the water flow guide mechanism 3 and impact the filter mechanism 2, the water flows into the outer side of the filter mechanism 2 through the filter mechanism 2 and is discharged out of the housing 1 through the water discharge pipe 14, the particles fall to the discharging pipe 13 and are discharged, so that the particle water separation is realized, the particle retention on the filter mechanism 2 is effectively avoided through the impact of the water flow, and the particle dehydration efficiency is improved.

Referring to fig. 2, 3 and 4, the supporting mechanism 4 in this embodiment includes four supporting rods 41 vertically placed in the housing 1, the bottoms of the four supporting rods 41 are fixedly connected with the housing 1 through two cross rods 42, the tops of the four supporting rods 41 penetrate through the upper sealing cover 111 and are fixedly connected with the upper sealing cover 111 through nuts, a plurality of supporting plates 43 are jointly arranged on the four supporting rods 41, the number of the supporting plates 43 in this embodiment is four, each supporting rod 41 penetrates through the supporting plate 43, the four supporting plates 43 are arranged at intervals along the vertical direction, a plurality of fixing rings 44 are sleeved on each supporting rod 41, each supporting plate 43 corresponds to two fixing rings 44, the supporting plates 43 are located between the two fixing rings 44, a notch 45 is formed in each fixing ring 44, fixing screws 46 are connected with the fixing rings 44 through threads, the fixing screws 46 sequentially penetrate through the fixing rings 44 on two sides of the notch 45 from the side walls of the fixing rings 44, supporting ring pieces 47 are arranged on the supporting plates 43, annular through holes are formed in the middle of the supporting ring pieces 47, and the upper sides and the lower sides of the supporting ring pieces 47 extend out of the supporting plates 43 respectively.

Referring to fig. 2, the filter mechanism 2 in this embodiment includes an annular straight screen 21 and a reducing screen 22, the number of the annular straight screen 21 and the supporting plate 43 can be determined by itself according to the requirement of particle-water separation, the number of the annular straight screens 21 in this embodiment is three, the annular straight screen 21 and the reducing screen 22 are arranged in the vertical direction, the reducing screen 22 is located between the two annular straight screens 21, the diameter of the reducing screen 22 is gradually reduced from the side close to the feed inlet 12 toward the side away from the feed inlet 12, the caliber of the annular straight screen 21 above the reducing screen 22 is the same as the large-end caliber of the reducing screen 22, the supporting ring piece 47 is inserted into the annular straight screen 21 and the reducing screen 22, the annular straight screen 21 above the supporting plate 43 and the reducing screen 22 are abutted against the supporting plate 43, the topmost annular straight screen 21 is abutted against the upper cover 111, and the feed inlet 12 is located between the annular straight screens 21.

Referring to fig. 2, 3 and 5, an opening 211 is formed in the annular straight screen 21, the opening 211 is arranged to enable the annular straight screen 21 to form two end faces in the annular direction, the two end faces of the annular straight screen 21 are outwards bent to form folded edges 212, the two folded edges 212 are located on two sides of the opening 211, and the two folded edges 212 are fixedly connected with nuts through bolts.

Referring to fig. 2, the water flow guiding mechanism 3 in this embodiment includes a supporting cylinder 31, a sidewall guiding cap 32 and a top guiding cap 33, the supporting cylinder 31 is provided with a reducing inclined plane 37 matching with the reducing screen 22, the supporting cylinder 31 is arranged along the vertical direction, the supporting cylinder 31 is located in the annular straight screen 21, a flow channel 34 is formed between the supporting cylinder 31 and the annular straight screen 21 and between the supporting cylinder 31 and the reducing screen 22, the bottom of the supporting cylinder 31 is fixedly connected with a supporting ring piece 47 through a connecting rod 35, the sidewall guiding cap 32 is sleeved on the supporting cylinder 31 and is arranged along the length direction of the supporting cylinder 31, the number of the sidewall guiding caps 32 is two according to the grain-water separation requirements of different-yield and different-flow grain cutting machines, the top guiding cap 33 is a conical plate with a downward opening, the top guiding cap 33 is located at the top of the supporting cylinder 31, the feeding port 12 is located right above the top guiding cap 33, the distance between the sidewall guiding cap 32 and the annular straight screen 22 is gradually increased from one side of the sidewall guiding cap 32 near the feeding port 12 to one side far from the feeding port 12, the top cap 32 is provided with a slope guiding cap 36 with the same angle as the top guiding cap 33, and the top guiding cap 33 is provided with a slope guiding cap 33.

When the annular straight screen 21 and the reducing screen 22 are installed, the fixing rings 44 are sleeved on the supporting rods 41, the supporting plates 43 are sleeved on the supporting rods 41, the other fixing ring 44 is sleeved on the supporting rods 41, the fixing screws 46 are screwed to enable the fixing rings 44 to be abutted against the supporting rods 41, meanwhile, the two fixing rings 44 squeeze the supporting plates 43, so that the supporting plates 43 are installed and fixed, the annular straight screen 21 is sleeved on the supporting ring pieces 47, then the second supporting plates 43 are installed, the annular straight screen 21 is sleeved on the supporting ring pieces 47 on the second supporting plates 43, then the nuts are screwed on the bolts to enable the annular straight screen 21 to be abutted against the supporting ring pieces 47, the installation convenience of the annular straight screen 21 is improved, meanwhile, the stability of connection between the annular straight screen 21 and the supporting ring pieces 47 is improved, and the two ends of the reducing screen 22 are sleeved on the supporting ring pieces 47 on the same side respectively.

When the particle water flows in from the feed inlet 12, the particle water firstly falls onto the top guide cap 33, and the material bearing table 36 generates certain resistance to the flow of the particle water, so that the flow speed of the particle water can be reduced, the flow time of the particle water in the separation device is prolonged, the contact time of the particle in the annular straight screen 21 and the reducing screen 22 is prolonged, and the particle water separation effect is improved; the top guide cap 33 firstly guides the particle water to impact the annular straight screen 21, then the particles fall onto the reducing screen 22, the particles flow along the reducing screen 22, the particle water separation time is prolonged, and the particle water separation can be more thorough; then particles flow downwards along the flow channel 34, the particles are impacted by the side wall guide caps 32 to the annular straight screen 21, the water flow flows from top to bottom, the annular straight screen 21 is vertically arranged, the water flow is guided by the side wall guide caps 32 to impact the annular straight screen 21 from the side surface to carry out particle-water separation, and the particles are effectively prevented from being detained on the annular straight screen 21 and the reducing screen 22, so that the particle-water separation efficiency is high.

The annular straight screen 21 and the reducing screen 22 are arranged along the vertical direction, and the filtering area of the annular straight screen 21 can be determined by the height of the filtering mechanism 2, so that a larger filtering area can be arranged in a smaller space, the filtering effect is improved, and meanwhile, the space occupation of the annular straight screen 21 is reduced; in addition, the filtering efficiency of the grain-water separation device can be adjusted by arranging different numbers of side wall guide caps 32 and/or different numbers of annular straight screens 21 on the supporting cylinder 31 along the vertical direction, so that the grain-water separation requirements of grain-cutting machines with different yields and different flow rates are met, and the flexibility of separation adjustment of the grain-water separation device is improved.

Referring to fig. 2, two guide plates 15 are arranged on the side wall of the feed inlet 12 in a crossing manner, the two guide plates 15 are arranged vertically, and the guide plates 15 are fixedly arranged with the side wall of the feed inlet 12; when the grain water enters the housing 1 from the feed inlet 12, the feed inlet 12 is divided into four identical spaces by the guide plate 15, so that the grain water is distributed more uniformly on the top guide cap 33.

Referring to fig. 6, an operation opening 161 is formed in a casing 1, a cover plate 162 for blocking the operation opening 161 is formed in the casing 1, the cover plate 162 is rotatably arranged with the casing 1 through a hinge 163, the other side of the cover plate 162 is connected with the casing 1 through two lock catches 164, and the lock catches 164 in the embodiment are spring lock catches 164; when abnormality occurs in the process of separating the particles from the water in the housing 1, the lock catch 164 is pulled to release the fixation of the cover plate 162, then the cover plate 162 is pulled to rotate so that the operation port 161 is opened, and then the operator can handle the abnormal situation through the operation port 161, thereby improving the convenience of handling the abnormal situation.

The implementation principle of the particle-water separation device of the large-yield particle cutting system provided by the embodiment of the application is as follows: when the granular water is separated, the annular straight screen 21, the reducing screen 22 and the supporting cylinder 31 are installed in the housing 1 through the supporting mechanism 4, then the granular water enters the housing 1 from the feed inlet 12, the granular water falls onto the top guide cap 33, the granular water is guided by the top guide cap 33 to strike the annular straight screen 21, the struck granular water falls onto the reducing screen 22 and slides along the reducing screen 22, then flows along the flow channel 34 and continuously strikes the annular straight screen 21 under the guidance of the side wall guide cap 32, the screened granules are discharged through the discharge pipe 13, and the separated water is discharged from the drain pipe 14.

The above embodiments are not intended to limit the scope of the present application, so: all equivalent changes in structure, shape and principle of the application should be covered in the scope of protection of the application.

Claims (10)

1. A granule water separator of a large-yield granule cutting system is characterized in that: including housing (1), be equipped with feed inlet (12) on housing (1), be equipped with filtering mechanism (2) in housing (1), filtering mechanism (2) are arranged along the water flow direction, filtering mechanism (2) with housing (1) are connected through supporting mechanism (4), be equipped with rivers guiding mechanism (3) on supporting mechanism (4), rivers guiding mechanism (3) are used for guiding water and granule towards filtering mechanism (2) flow.

2. A high throughput pelletizing system pellet water separation apparatus as claimed in claim 1, wherein: the supporting mechanism (4) comprises a supporting rod (41) arranged in the housing (1), a supporting plate (43) is arranged on the supporting rod (41), and a supporting ring piece (47) is arranged on the supporting plate (43);

the filtering mechanism (2) comprises a plurality of annular straight screens (21), the annular straight screens (21) are arranged along the water flow direction, and the supporting ring piece (47) is inserted into two adjacent annular straight screens (21), and the two adjacent annular straight screens (21) are in interference with the supporting plate (43).

3. A high throughput pelletizing system pellet water separation apparatus as claimed in claim 2, wherein: the support rod (41) penetrates through the support plate (43), two fixing rings (44) are sleeved on the support rod (41), the support plate (43) is located between the two fixing rings (44), each fixing ring (44) is provided with a notch (45), each fixing ring (44) is provided with a fixing screw (46), and the fixing screws (46) are inserted into the fixing rings (44) on two sides of each notch (45) and are in threaded connection with the fixing rings (44).

4. A high throughput pelletizing system pellet water separation apparatus as claimed in claim 2, wherein: the water flow guiding mechanism (3) comprises a supporting cylinder (31) and a side wall guiding cap (32) which are arranged in the annular straight screen (21), a flow channel (34) is formed between the supporting cylinder (31) and the annular straight screen (21), the side wall guiding cap (32) is circumferentially arranged along the supporting cylinder (31), and the distance from the side wall guiding cap (32) to the annular straight screen (21) is gradually increased from one side, close to the feed inlet (12), of the side wall guiding cap (32) to one side, away from the feed inlet (12).

5. The high-yield pelleting system pellet water separation device as claimed in claim 4, wherein: the water flow guiding mechanism (3) further comprises a top guiding cap (33), the inclination angle of the top guiding cap (33) is the same as that of the side wall guiding cap (32), the top guiding cap (33) is located between the feeding hole (12) and the supporting cylinder (31), and a material bearing table (36) is arranged on the top guiding cap (33).

6. The high-yield pelleting system pellet water separation device as claimed in claim 4, wherein: the filtering mechanism (2) further comprises a reducing screen (22), the supporting ring piece (47) is inserted into the reducing screen (22), and the diameter of the reducing screen (22) gradually decreases from the side close to the feed inlet (12) to the side far away from the feed inlet (12).

7. The high-yield pellet separation device of claim 6, wherein: the novel straight screen is characterized in that an opening (211) is formed in the annular straight screen (21), two ends of the annular straight screen (21) are bent to form folded edges (212), two folded edges (212) are located on two sides of the opening (211), the two folded edges (212) are connected with nuts through bolts, and the folded edges (212) are lapped on the supporting plate (43).

8. A high throughput pelletizing system pellet water separation apparatus as claimed in claim 2, wherein: the circular straight screen (21) is provided with a discharge pipe (13), the discharge pipe (13) penetrates through the bottom wall of the housing (1), and the bottom wall of the housing (1) is provided with a drain pipe (14).

9. A high throughput pelletizing system pellet water separation apparatus as claimed in claim 1, wherein: two material guide plates (15) which are arranged in a crossing mode are arranged on the side wall of the feeding hole (12), and the two material guide plates (15) are vertically arranged.

10. A high throughput pelletizing system pellet water separation apparatus as claimed in claim 1, wherein: the novel anti-theft device is characterized in that an operation port (161) is formed in the housing (1), a cover plate (162) for blocking the operation port (161) is arranged on the housing (1), the cover plate (162) and the housing (1) are rotatably arranged through a hinge (163), and the cover plate (162) and the housing (1) are fixed through a lock catch (164).