CN118091089A - Soil detector for planning homeland space - Google Patents

Abstract

The invention relates to the technical field of soil detection and discloses a soil detector for planning a homeland space, which comprises a detector display screen, a probe arranged at the bottom of the detector display screen, a sensor arranged at the bottom of the probe and a protection part, wherein the probe is arranged on the bottom of the detector display screen; the protective component is arranged around the probe and comprises a pushing component arranged at the top of the probe, a rotating component arranged at the bottom of the pushing component and a protective component arranged at the bottom of the pushing component; the outside of the protection component is provided with an insertion component, and the insertion component comprises an insertion component arranged around the protection component. After detection, the pressing plates on two sides are pushed upwards, and then rotated into the pressing holes when pushed to the tail ends of the pushing holes, so that the probes are recovered and locked in the insertion tube, the storage function is realized, the protection of the probes is realized, and the service life of the probes is prolonged.

Description

Soil detector for planning homeland space

Technical Field

The invention relates to the technical field of soil detection, in particular to a soil detector for planning a homeland space.

Background

A soil tester is a device for testing various chemical substances, physical properties and biological indicators in soil. It can help agricultural scientists, environmental monitoring agencies and other professionals in related fields to understand the quality and condition of soil in order to better manage and protect land resources. In soil testing of some soils with relatively high sand content, the amount of stone in the soil typically increases. Soil with a high sand content means that mineral particles in the soil are surrounded by more impurities. Whereas stones are themselves solid objects composed of minerals, they may form larger spaces between the soil particles when the sand-laden soil contains more stones. When the soil detector is inserted into soil for detection, the sensor at the top of the detector can be extruded with stones in the soil, so that the sensor at the end part of the soil detector is damaged.

The patent with the publication number of CN219552417U discloses a soil detector, which is used for directly inserting the soil detector into soil for detection, and the support rod is pulled to slide out of the storage groove, and simultaneously rotates on the rotating piece, so that the extending rod supports the detector, the effect of supporting the soil detector is realized, and the soil detector is prevented from tilting when a probe is inserted into the soil;

However, the following drawbacks remain in the prior art:

When detecting with soil detector, directly insert the probe in soil, in the higher soil of sand content, because can exist hard materials such as stone in the soil of sand content height, at probe male in-process, can make the bottom of probe direct with the stone extrusion, when the extrusion, because the stone is in soil, when the probe extrusion stone, the stone can not remove easily to cause probe bottom sensor to continuously receive the extrusion, cause the damage of sensor easily, reduced detector's life.

Disclosure of Invention

In view of the problems in the prior art that the detector is easy to cause the end part of the probe to be directly extruded to stones in the process of inserting the detector into soil for detection, the probe sensor is damaged, and the service life of the detector is reduced, the soil detector is planned in a homeland space.

The aim is that: in the detector inserting process, the damage of the probe caused by the fact that the probe extrudes hard materials such as stones is avoided, and the service life of the detector is prolonged.

The technical scheme of the invention is that the soil detector for planning the homeland space comprises a detector display screen, a probe arranged at the bottom of the detector display screen, a sensor arranged at the bottom of the probe and a protection component;

The protection component is arranged around the probe and comprises a pushing component arranged at the top of the probe, a rotating component arranged at the bottom of the pushing component and a protection component arranged at the bottom of the pushing component;

The outside of protection part is provided with the insert part, the insert part is including setting up in the peripheral insert assembly of protection assembly, insert the subassembly and include the insert tube, be a plurality of insert plates that the annular array set up in the insert tube bottom, set up the discharge port between two insert plates to and set up the discharge surface in insert plate both sides.

Adopt above-mentioned technical scheme, when carrying out soil detection, insert the insert tube in the soil, both hands press the promotion subassembly for rotating assembly drives the protection subassembly and rotates, and the protection subassembly rotates in the soil, in the rotation in-process, with some big stones in the soil go out through the exhaust port, push some little stones around the protection subassembly, avoid the probe when inserting, cause the damage to the sensor of lateral wall and bottom of probe, the discharge face is the inclined plane, be convenient for extrude the discharge port department with big stone.

Further, the width of the discharge hole is larger than that of the insertion plate, and one end of the discharge hole is semicircular.

By adopting the technical scheme, the width of the discharge hole is larger than the width of the insertion plate, so that some larger stones are conveniently extruded out from the discharge hole, and the smaller insertion plate is arranged, so that the insertion pipe is easier to be inserted into soil, the insertion pipe is also convenient to be pulled out, more soil is prevented from being brought out by the insertion pipe during pulling out, and the cleaning of the insertion pipe is not facilitated.

Further, the pushing assembly comprises a pushing plate arranged at one end of the inside of the insertion tube, pressing plates symmetrically arranged at two sides of the pushing plate, pressing holes symmetrically arranged at one end of the insertion tube, and pushing holes arranged at one side of the pressing holes.

By adopting the technical scheme, when the insertion tube is inserted, the pressing plates on two sides are directly pressed down, the whole insertion tube is extruded in the pressing hole at the moment, so that the insertion tube can be firstly inserted into soil, then the pressing plates are rotated, the pressing plates are rotated to one side of the pushing hole, the pressing plates are vertically pushed downwards at the moment, the pushing plates are driven to move downwards in the insertion tube, the pushing plates drive the detector to be inserted into the soil, after detection, the pressing plates on two sides are pushed upwards, and then the pushing plates are rotated into the pressing hole when pushed to the tail end of the pushing hole, the probe is recovered and locked in the insertion tube, the storage function is realized, meanwhile, the protection of the probe is also realized, and the service life of the probe is prolonged.

Further, the rotating assembly comprises a rotating plate arranged in the pushing plate, a rotating surface arranged at the bottom of the rotating plate, a rotating block arranged at one side of the bottom of the rotating plate, a rotating ball arranged at one side of the rotating block and a rotating groove arranged in the insertion tube.

By adopting the technical scheme, when pushing the pressing plate downwards, the pushing plate drives the rotating plate inside the pushing plate to move downwards, the rotating surface reduces the rotating resistance of the rotating plate when the rotating plate is limited, the rotating efficiency is improved, and when the rotating plate is pushed to move downwards, the rotating ball on one side of the rotating block moves in the rotating groove, so that the rotating plate synchronously rotates in the downward moving process.

Further, the diameter of the rotating ball is larger than the width of the pushing hole.

By adopting the technical scheme, when the rotary ball rotates in the rotary groove, the rotary ball with the diameter larger than the width of the push hole can smoothly pass through the push hole, so that the rotary ball rotates along the rotary groove, and the normal rotation of the rotary assembly is ensured.

Further, the protection component comprises a first protection strip which is arranged at the bottom of the rotating plate in a ring-shaped array, a second protection strip which is arranged at one end of the first protection strip, the first protection strip is in a thread shape, and the first protection strip and the second protection strip are arranged on the bevel surface at one side of the bottom of the first protection strip and the bevel surface at one side of the bottom of the second protection strip.

By adopting the technical scheme, the rotating assembly during operation, the rotating plate is driven to rotate, and then the first protection strip at the bottom of the rotating plate is driven to rotate, the first protection strip is in a threaded shape, so that after the probe is inserted into soil, the probe can rotate in the soil, hard impurities such as stones in the soil are stirred, the side wall of the probe is kept away from, the hard impurities such as stones are prevented from scratching the side wall of the probe during insertion, the quick insertion of the probe is realized, the service life of the probe is prolonged, the first protection strip is driven to rotate during rotation, the first protection strip firstly rotates into the soil, a plurality of larger stones are pushed downwards, the first protection strip and the second protection strip can be quickly rotated in the soil due to the arrangement of the inclined surface, the rotation efficiency of the first protection strip and the second protection strip is improved, and the threaded shape of the first protection strip can be quickly introduced into the soil during rotation.

Further, the bottoms of the second protection strips are pointed, the bottoms of the four second protection strips are gathered together, the second protection strips are S-shaped, and rotating parts are arranged at the bottoms of the four second protection strips.

By adopting the technical scheme, the second protection bar bottom is pointed setting and is convenient for the second protection bar when rotating, insert in the soil fast, improved the efficiency that the second protection bar inserted soil, the second protection bar is when rotating, the bottom that its was gathered together the form can rotate more easily and get into in the soil, and at the in-process of rotating into soil, the second protection bar of S shape extrudees the stone that is great to the extrusion all around of probe to extrude through the discharge port, avoid the sensor at probe top and the hard extrusion between the great stone, avoided the damage of sensor.

Further, the bottom of rotation portion is annular array and is provided with the third protection strip, and the one end and the lateral wall fixed connection of first protection strip of third protection strip, the third protection strip sets up between two second protection strips, four the one end of third protection strip is the form of gathering together.

By adopting the technical scheme, after bigger stones are extruded out through the discharge holes by the second protective strips, some smaller stones enter the rotating part in the rotation process of the second protective strips, the second protective strips rotate to enable the smaller stones to be extruded out from one side of the third protective strips, the extrusion of smaller stones to the probe tip sensor is further avoided, the damage of the sensor is caused, the setting of the gathered third protective strips enables the smaller stones entering the rotating part to be extruded out from the gap between the two adjacent second protective strips, the protectiveness to the probe is further improved, the extruded smaller stones are stirred by the first protective strips in the rotation process, the smaller stones are prevented from being fixedly stopped on the side wall of the probe, the probe is prevented from being scratched after being inserted, and the smaller stones can be rotated and stirred to the outer side of the first protective strips.

Compared with the prior art, the invention has the following beneficial effects:

1. After detection, the pressing plates on two sides are pushed upwards, and then rotated into the pressing holes when pushed to the tail ends of the pushing holes, so that the probes are recovered and locked in the insertion tube, the storage function is realized, the protection of the probes is realized, and the service life of the probes is prolonged.

2. During operation of the rotating assembly, the rotating plate is driven to rotate, and then the first protective strip at the bottom of the rotating plate is driven to rotate, and the first protective strip is in a threaded shape, so that after the probe is inserted into soil, the probe can rotate in the soil, hard impurities such as stones in the soil are stirred, the side wall of the probe is kept away from, the side wall of the probe is prevented from being scratched by the hard impurities such as stones when the probe is inserted, and the rapid insertion of the probe is realized.

3. After bigger stone is extruded by the second protection bar through the discharge hole, some less stones enter into the rotating part in the rotation process of the second protection bar, and the second protection bar rotates to enable the smaller stones to be extruded out from one side of the third protection bar, so that extrusion of smaller stones to the probe tip sensor is further avoided, the protectiveness of the probe is further improved, influence of Dan Toudeng hard substances on soil measurement results is eliminated, measurement accuracy is improved, and the service life of the sensor is prolonged.

Drawings

FIG. 1 is a schematic perspective view of the whole structure of the present invention;

FIG. 2 is a schematic view of the overall structure of the interior of the present invention;

FIG. 3 is a schematic view of the overall structure of the insert assembly of the present invention;

FIG. 4 is a schematic view of the overall structure of the pushing assembly of the present invention;

FIG. 5 is a schematic view of the overall structure of the rotary assembly of the present invention;

FIG. 6 is a schematic view of the overall structure of the protective assembly of the present invention;

FIG. 7 is a schematic view of a partially enlarged structure of the shielding assembly of the present invention;

FIG. 8 is a schematic perspective view of a first guard bar according to the present invention;

FIG. 9 is a schematic diagram showing the overall structure of a first guard bar and a second guard bar according to the present invention;

FIG. 10 is a schematic diagram of the overall structure of a third guard bar according to the present invention.

In the figure:

A probe; 11. a sensor; 2. an insert assembly; 21. an insertion tube; 22. an insertion plate; 23. a discharge hole; 24. a discharge surface; 3. a pushing assembly; 31. a pushing plate; 32. pressing the plate; 33. pressing the hole; 34. a push hole; 4. a rotating assembly; 41. a rotating plate; 42. a rotating surface; 43. a rotating block; 44. a spin ball; 45. a rotary groove; 5. a protective assembly; 51. a first guard bar; 52. a second guard bar; 53. chamfering; 6. a rotating part; 7. and a third guard bar.

Detailed Description

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

Embodiment 1, refer to fig. 1-3, for a first embodiment of the present invention, provide a soil detector for planning a homeland space, which includes a detector display screen, a probe 1 installed at the bottom of the detector display screen, a sensor 11 installed at the bottom of the probe 1, and a protection component; the protective component is arranged around the probe 1 and comprises a pushing component 3 arranged at the top of the probe 1, a rotating component 4 arranged at the bottom of the pushing component 3 and a protective component 5 arranged at the bottom of the pushing component 3; the outside of the protection component is provided with an insertion component, the insertion component comprises an insertion component 2 arranged around the protection component 5, the insertion component 2 comprises an insertion pipe 21, a plurality of insertion plates 22 which are fixedly connected to the bottom of the insertion pipe 21 in an annular array, a discharge hole 23 which is arranged between the two insertion plates 22, and discharge surfaces 24 which are arranged on two sides of the insertion plates 22.

Specifically, when carrying out soil and examining, insert the soil with insert tube 21 in, both hands are pressed and are promoted the subassembly 3 for rotating assembly 4 drives protection component 5 and rotate, and protection component 5 rotates in soil, and at the rotation in-process, will some big stones in the soil go out through discharge hole 23, push some little stones around protection component 5, avoid probe 1 when inserting, cause the damage to the sensor 11 of the lateral wall and the bottom of probe 1, discharge surface 24 is the inclined plane, be convenient for extrude discharge hole 23 department with big stone.

Referring to fig. 1 to 3, the width of the discharge hole 23 is greater than the width of the insertion plate 22, and one end of the discharge hole 23 has a semicircular shape.

Specifically, the width of the discharge hole 23 is greater than the width of the insertion plate 22, so that some larger stones are conveniently extruded from the discharge hole 23, and the smaller insertion plate 22 is arranged, so that the insertion tube 21 is easier to be inserted into soil, and the insertion tube 21 is also convenient to be pulled out, so that the insertion tube 21 is prevented from bringing more soil during pulling out, and cleaning of the insertion tube 21 is not facilitated.

Referring to fig. 1 to 4, the pushing assembly 3 includes a pushing plate 31 slidably coupled to one end of the inside of the insertion tube 21, pressing plates 32 symmetrically fixedly coupled to both sides of the pushing plate 31, a pressing hole 33 symmetrically formed at one end of the insertion tube 21, and a pushing hole 34 formed at one side of the pressing hole 33.

Specifically, when the insertion tube 21 is inserted, the pressing plates 32 on two sides are directly pressed down, at this time, the pressing plates 32 press the whole insertion tube 21 in the pressing holes 33, so that the insertion tube 21 can be firstly inserted into soil, then the pressing plates 32 are rotated, so that the pressing plates 32 are rotated to one side of the pushing holes 34, at this time, the pressing plates 32 are vertically pushed downwards, the pushing plates 31 are driven to move downwards in the insertion tube 21, the pushing plates 31 drive the detector to be inserted into the soil, after detection, the pressing plates 32 on two sides are pushed upwards, when the pushing plates are pushed to the tail ends of the pushing holes 34, the pushing plates are rotated into the pressing holes 33 again, the probe 1 is recovered and locked in the insertion tube 21, the protection of the probe 1 is realized, and the service life of the probe 1 is prolonged.

Embodiment 2, referring to fig. 1-5, is a second embodiment of the present invention, which differs from the first embodiment in that: the rotating assembly 4 includes a rotating plate 41 rotatably connected to the inside of the pushing plate 31, a rotating surface 42 provided at the bottom of the rotating plate 41, a rotating block 43 fixedly connected to one side of the bottom of the rotating plate 41, a rotating ball 44 fixedly connected to one side of the rotating block 43, and a rotating groove 45 provided in the inside of the insertion tube 21.

Specifically, when the pressing plate 32 is pushed downward, the pushing plate 31 drives the rotating plate 41 inside the pushing plate to move downward, the rotating surface 42 reduces the rotating resistance of the rotating plate 41 while limiting the rotating plate 41, the rotating efficiency is improved, and when the rotating plate 41 is pushed to move downward, the rotating ball 44 on one side of the rotating block 43 moves in the rotating groove 45, so that the rotating plate 41 synchronously rotates in the downward moving process.

Referring to fig. 5, the diameter of the swivel ball 44 is greater than the width of the push hole 34.

Specifically, when the rotating ball 44 rotates in the rotating groove 45, the rotating ball 44 with a diameter larger than the width of the pushing hole 34 can smoothly pass through the pushing hole 34 after passing through the pushing hole 34, so that the rotating ball 44 rotates along the rotating groove 45, and the normal rotation of the rotating assembly 4 is ensured. The rest of the structure is the same as that of embodiment 1.

Embodiment 3, referring to fig. 1-8, is a third embodiment of the present invention, which differs from the second embodiment in that: the protection component 5 comprises a first protection strip 51 which is fixedly connected to the bottom of the rotating plate 41 in an annular array, a second protection strip 52 which is fixedly connected to one end of the first protection strip 51, the first protection strip 51 is in a thread shape, and a bevel 53 which is arranged on one side of the bottoms of the first protection strip 51 and the second protection strip 52 is arranged.

Specifically, the rotating assembly 4 during operation, the rotating plate 41 is driven to rotate, and then the first protection strip 51 at the bottom of the rotating plate 41 is driven to rotate, the first protection strip 51 is in a threaded mode, after the probe 1 is inserted into soil, the probe can rotate in the soil, hard impurities such as stones in the soil are stirred, the side wall of the probe 1 is kept away from, the hard impurities such as stones are prevented from scratching the side wall of the probe 1 during insertion of the probe 1, the quick insertion of the probe 1 is achieved, the service life of the probe 1 is prolonged, when the first protection strip 51 drives the first protection strip 51 to rotate during rotation, the first protection strip 51 firstly rotates into the soil, a plurality of larger stones are pushed downwards, the first protection strip 51 and the second protection strip 52 can rotate in the soil quickly due to the arrangement of the inclined planes 53, the rotation efficiency of the first protection strip 51 and the second protection strip 52 is improved, and the threaded mode of the first protection strip 51 can enter the soil quickly during rotation.

Referring to fig. 1 to 9, the bottoms of the second guard bars 52 are pointed, the bottoms of the four second guard bars 52 are gathered, the second guard bars 52 are S-shaped, and the bottoms of the four second guard bars 52 are provided with the rotating parts 6.

Specifically, the setting that second protection strip 52 bottom is the cusp is convenient for second protection strip 52 when rotating, inserts in the soil fast, has improved the efficiency that second protection strip 52 inserted the soil, and second protection strip 52 when rotating, and the bottom of its gathering form can rotate more easily and get into in the soil, and at the in-process of rotating into soil, the second protection strip 52 of S-shaped extrudees great stone to probe 1 all around to extrude out through discharge port 23, avoid the rigid extrusion between the sensor 11 at probe 1 top and the great stone, avoided the damage of sensor 11.

Referring to fig. 1-10, the bottom of the rotating part 6 is fixedly connected with third protection bars 7 in a ring array, one ends of the third protection bars 7 are fixedly connected with the side wall of the first protection bars 51, the third protection bars 7 are arranged between two second protection bars 52, and one ends of the four third protection bars 7 are gathered.

Specifically, after the bigger stones are extruded by the second protection bars 52 through the discharge holes 23, some smaller stones enter the rotary part 6 in the second protection bars 52 in the rotating process, the second protection bars 52 rotate to enable the smaller stones to be extruded out from one side of the third protection bars 7, further damage to the sensor 11 caused by extrusion of the smaller stones to the tip sensor 11 of the probe 1 is avoided, the clustered third protection bars 7 enable the smaller stones entering the rotary part 6 to be extruded out from gaps between the two adjacent second protection bars 52, the protectiveness to the probe 1 is further improved, influence of Dan Toudeng hard substances on soil measurement results is eliminated, the measuring accuracy is improved, the service life of the sensor 11 is prolonged, the extruded smaller stones are stirred by the first protection bars 51 in the rotating process, the smaller stones are prevented from being fixedly stopped on the side wall of the probe 1, the probe 1 is scratched after the probe 1 is inserted, the safety of equipment is improved, and the small stones can be stirred to the outer side of the first protection bars 51. The rest of the structure is the same as that of embodiment 2.

The working principle of the invention is as follows:

When the soil is detected, the pressing plates 32 are pressed down by both hands, the inserting tube 21 is firstly inserted into the soil by the pressing plates 32 in the pressing holes 33, then the pressing plates 32 are rotated and then the pressing plates 32 are continuously pressed down, so that the pressing plates 32 move down along the pushing holes 34, the pushing plates 31 move down by the downward movement of the pressing plates 32, the pushing plates 31 push the rotating plates 41 to move down, the rotating balls 44 move in the rotating grooves 45, the rotating blocks 43 drive the rotating plates 41 to rotate, the rotating plates 41 rotate to drive the first protective strips 51 and the second protective strips 52 at the bottom of the rotating plates to rotate, the second protective strips 52 enter the soil in the rotating process, the probe 1 enters the soil along with the rotation of the second protective strips 52, and the second protective strips 52 press hard impurities such as larger stones in the soil downwards and outwards of the second protective strips 52 in the rotating process, the large stones are extruded to the discharge holes 23, so that the sensor 11 is prevented from being damaged due to the fact that the large stones extrude the sensor 11 at the top end of the probe 1, the small stones enter the rotating part 6 in the process of rotating the second protective strip 52, are extruded and discharged by the third protective strip 7 in the process of continuously rotating the second protective strip 52 and are far away from the end of the probe 1, the protection of the end of the probe 1 is further improved, the small stones extruded and discharged by the third protective strip 7 enter between the first protective strips 51 and are stirred when the first protective strip 51 rotates, the small stones are extruded to the outer side of the first protective strip 51, the side wall of the probe 1 is prevented from being clung to the scratch of the side wall of the probe 1, and the service life of the detector is prolonged.

It should be noted that the above embodiments are only for illustrating the technical solution of the present invention and not for limiting the same, and although the present invention 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 invention may be modified or substituted without departing from the spirit and scope of the technical solution of the present invention, which is intended to be covered in the scope of the claims of the present invention.

Claims (8)

1. The soil detector for planning the homeland space comprises a detector display screen, a probe (1) arranged at the bottom of the detector display screen, and a sensor (11) arranged at the bottom of the probe (1), and is characterized by further comprising a protection component;

The protection component is arranged around the probe (1) and comprises a pushing component (3) arranged at the top of the probe (1), a rotating component (4) arranged at the bottom of the pushing component (3) and a protection component (5) arranged at the bottom of the pushing component (3);

The outside of protection part is provided with the insert part, the insert part is including setting up in insert subassembly (2) around protection subassembly (5), insert subassembly (2) are including insert pipe (21), are a plurality of insert board (22) that annular array set up in insert pipe (21) bottom, offer discharge port (23) between two insert board (22) to and offer in discharge face (24) of insert board (22) both sides.

2. A homeland space planning soil tester as claimed in claim 1, wherein: the width of the discharge hole (23) is larger than that of the insertion plate (22), and one end of the discharge hole (23) is semicircular.

3. A homeland space planning soil tester as claimed in claim 2, wherein: the pushing assembly (3) comprises a pushing plate (31) arranged at one end inside the insertion tube (21), pressing plates (32) symmetrically arranged at two sides of the pushing plate (31), pressing holes (33) symmetrically formed at one end of the insertion tube (21), and pushing holes (34) formed at one side of the pressing holes (33).

4. A homeland space planning soil tester according to claim 3, wherein: the rotating assembly (4) comprises a rotating plate (41) arranged in the pushing plate (31), a rotating surface (42) arranged at the bottom of the rotating plate (41), a rotating block (43) arranged at one side of the bottom of the rotating plate (41), a rotating ball (44) arranged at one side of the rotating block (43) and a rotating groove (45) arranged in the inserting tube (21).

5. The homeland space planning soil tester as claimed in claim 4, wherein: the diameter of the rotating ball (44) is larger than the width of the pushing hole (34).

6. The homeland space planning soil tester according to claim 5, wherein: the protection assembly (5) comprises a first protection strip (51) which is arranged at the bottom of the rotating plate (41) in an annular array, a second protection strip (52) which is arranged at one end of the first protection strip (51), the first protection strip (51) is in a thread shape, and a bevel (53) which is arranged at one side of the bottoms of the first protection strip (51) and the second protection strip (52) is arranged.

7. The homeland space planning soil tester as claimed in claim 6, wherein: the bottoms of the second protection strips (52) are pointed, the bottoms of four second protection strips (52) are gathered together, the second protection strips (52) are S-shaped, and rotating parts (6) are arranged at the bottoms of the four second protection strips (52).

8. The homeland space planning soil tester as claimed in claim 7, wherein: the bottom of rotation portion (6) is annular array and is provided with third protection strip (7), and the one end of third protection strip (7) is connected with the lateral wall fixed of first protection strip (51), third protection strip (7) set up between two second protection strips (52), four the one end of third protection strip (7) is the form of gathering together.