CN112792376B - Drilling workbench - Google Patents

Abstract

The invention provides a drilling measurement and control mechanism which is arranged on a base, wherein the base is provided with a bottom plate, a pair of side walls are vertically arranged on two sides of the bottom plate to define a longitudinal groove, a clamping mechanism is arranged on the base and is arranged along the longitudinal direction of the groove, and a pull rod supporting plate for accommodating a workpiece is provided; the drilling measurement and control mechanism comprises: the guide rail is arranged above the side wall of the base; the drilling platform comprises a mounting plate, a short guide rail fixed on the mounting plate and extending along the transverse direction of the base, and a placing plate slidably mounted on the short guide rail to provide a guide hole, so that the guide hole can be aligned with a workpiece on the pull rod supporting plate. The drilling platform of the drilling measurement and control mechanism can move along the longitudinal direction of the guide rail and move along the transverse direction of the short guide rail to determine the drilling position, and the drill bit is guided by the guide hole to drill.

Description

Drilling workbench

Technical Field

The invention belongs to the technical field of mobile communication auxiliary instruments, and particularly relates to a drilling workbench.

Background

The pull rod is used for driving the antenna and is an important component of the antenna. The pull rod is generally made of glass steel and is in a flat strip shape. Generally, one end of the pull rod is provided with 2 small through holes for being connected with a screw transmission mechanism of the antenna, and the other positions are provided with a plurality of small through holes for being connected with a phase shifter of the antenna. Because the arrangement of the screw driving mechanism and the phase shifter of each antenna is generally different, the length and the drilling position of the used pull rod of each antenna can be adaptively changed. The pull rod made of glass fiber reinforced plastic is generally formed by pultrusion, the cross section of the pull rod is generally in the specification of 9.8mm by 2.5mm and 10mm by 5mm, and the diameter of the small through hole on the pull rod is generally in the specification of 3.1mm and 4.1 mm. Due to the fact that the area and the length of the pull rod and the diameter and the position of the small through hole are different, the pull rod cannot be produced in a large scale. Therefore, the small through hole on the pull rod is usually obtained by drilling, and due to the fact that the area and the length of the pull rod and the diameter and the position of the small through hole are changed frequently, cutter replacement and cutter position adjustment are troublesome during drilling.

At present, the pull rod drilling method commonly used for drilling holes can directly use measuring tools such as a vernier caliper, a rigid ruler, a steel ring ruler and the like to measure and position the drilling position on a pull rod, and a pistol drill is used for drilling holes, so that a large amount of time is needed to be spent on the method, and the processing efficiency is influenced. And the method can not accurately determine the drilling position, so that the drilling on the pull rod is not accurate, the position of the through hole is deviated, the pull rod is not suitable for being used in an antenna, and the pull rod is scrapped.

Therefore, there is a need for a tool that can precisely drill holes in tie rods to facilitate precise drilling.

Disclosure of Invention

The invention aims to provide a drilling workbench which is convenient for accurately determining a drilling position.

The invention is suitable for the purpose of the invention and adopts the following technical scheme:

the invention provides a drilling workbench which comprises a base, a clamping mechanism, a drilling measurement and control mechanism and a pressure control mechanism, wherein the drilling measurement and control mechanism is arranged on the base, the base is provided with a bottom plate, a pair of side walls are vertically arranged on two sides of the bottom plate to define a longitudinal groove, the clamping mechanism is arranged on the base and is arranged along the longitudinal direction of the groove, and a pull rod supporting plate for accommodating a workpiece is provided; the drilling measurement and control mechanism comprises:

the guide rail is arranged above the side wall of the base;

the drilling platform comprises a mounting plate, a short guide rail fixed on the mounting plate and extending along the transverse direction of the base, and a placing plate which is slidably arranged on the short guide rail to provide a guide hole, so that the guide hole can be aligned with a workpiece on the pull rod supporting plate;

the fixture includes:

the pair of positioning plates are arranged in parallel and are arranged at two sides of the pull rod supporting plate;

the connecting rod assembly is connected with the pair of positioning plates respectively to control the opening and closing of the pair of positioning plates and comprises a sliding rod, swinging rods and connecting blocks, one end of the sliding rod is arranged on the base plate in a liftable mode, the other end of the sliding rod penetrates through a pivoting shaft which is radially arranged on the base plate, two ends of the pivoting shaft are respectively pivoted with one ends of the two swinging rods, the other ends of the two swinging rods are respectively correspondingly pivoted with the two connecting blocks, and the two connecting blocks are locked with the two positioning plates.

Further, the drilling platform also comprises a screw knob for locking the mounting plate and the base to limit the mounting plate to run on the guide rail.

Further, a pair of lateral walls includes first lateral wall and second lateral wall, the first lateral wall outside is equipped with the scale of lengthwise extension, drilling workstation is equipped with the marker of indicating the scale on this scale in corresponding side.

Further, the drilling platform further comprises a locking bolt for locking the placing plate on the short guide rail so as to limit the placing plate to slide on the short guide rail.

Specifically, the bottom of the mounting plate is also provided with a sliding block used for sliding on a guide rail.

Preferably, the drilling platform further comprises a drilling guide member, the guide hole is formed in the drilling guide member, and the placing plate is provided with a placing hole for installing the drilling guide member.

Preferably, the drill guide is provided with a through hole for passing the drill bit therethrough, and one end of the through hole is provided with a guide port for guiding the drill bit.

Further, the drilling measurement and control mechanism further comprises a drilling machine, and the drilling machine is arranged on the placing plate.

Specifically, the drilling platform including vertical set up in place the stroke board of board with set up and drive on the stroke board the gliding slip table cylinder about the drilling machine.

Further, the drilling platform including set up in the revolving cylinder of slip table cylinder one side, revolving cylinder drives the drilling machine rotates.

Compared with the prior art, the invention has the following advantages:

first, the drilling table of the drilling measurement and control mechanism of the present invention can move along the longitudinal direction of the guide rail on the guide rail, and the drilling table can move in the transverse direction through the short guide rail, so that the specific drilling position on the drilling surface of the pull rod can be determined.

Secondly, the drilling measurement and control mechanism can guide the drilling to drill through the guide hole provided by the drilling measurement and control mechanism, so that accurate drilling is facilitated.

Drawings

The foregoing and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

fig. 1 is a schematic structural view of a drilling table according to an embodiment of the present invention.

Fig. 2 is a schematic structural diagram of a clamping mechanism according to an embodiment of the invention.

FIG. 3 is a schematic view of a linkage assembly of the clamping mechanism according to one embodiment of the present invention.

FIG. 4 is a side view of a linkage assembly of the clamping mechanism according to one embodiment of the present invention.

FIG. 5 is a schematic view in section I-I of the connecting rod assembly shown in FIG. 4.

FIG. 6 is a schematic J-J cross-sectional view of the connecting rod assembly shown in FIG. 4.

Fig. 7 is a first cross-sectional view in the transverse direction of a clamping mechanism of one embodiment of the invention.

Fig. 8 is a second cross-sectional view in the transverse direction of the clamping mechanism of one embodiment of the present invention.

Fig. 9 is an enlarged view of detail D of fig. 7.

FIG. 10 is a schematic view of a pull rod guide structure of a clamping mechanism according to an embodiment of the invention.

Fig. 11 is an enlarged view of detail B and detail C of fig. 10, wherein the left side is an enlarged view of detail B and the right side is an enlarged view of detail C.

Fig. 12 is a schematic structural diagram of a reference member of a clamping mechanism according to an embodiment of the invention, wherein the left side view is a schematic front view, and the right side view is a schematic back view.

FIG. 13 is a schematic diagram of the components associated with the puck in a pressure control mechanism according to one embodiment of the present invention.

Fig. 14 is a cross-sectional view in the transverse direction of the platen-related components in the pressure control mechanism of one embodiment of the present invention.

FIG. 15 is a schematic diagram of the position relationship between the pressing wheel and the pulling rod of the pressure-controlled mechanism according to one embodiment of the present invention.

Fig. 16 is a schematic structural diagram of a drilling measurement and control mechanism according to an embodiment of the present invention.

FIG. 17 is a cross-sectional view in the transverse direction of a borehole logging mechanism of one embodiment of the present invention.

FIG. 18 is a schematic diagram of a drill guide of a drill logging mechanism, according to an embodiment of the present invention, with FIG. A being a front view of the drill guide; b is a cross-sectional view in the S-S direction of the upper left drawing; c is a top view of the drill guide; figure D is a perspective view of the drill guide.

Fig. 19 is another structural diagram of the drilling measurement and control mechanism according to an embodiment of the present invention.

Fig. 20 is another structural view of a drilling table according to an embodiment of the present invention.

Fig. 21 is a schematic structural view of a drilling table equipped with a drilling machine according to an embodiment of the present invention.

Fig. 22 is a schematic structural view of a drilling measurement and control mechanism provided with a drilling machine according to an embodiment of the present invention.

Fig. 23 is a partially enlarged view of fig. 1.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below by referring to the drawings are exemplary only for the purpose of illustrating the present invention and are not to be construed as limiting the present invention.

As used herein, the singular forms "a", "an", "the" and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise. It will be further understood that the terms "comprises" and/or "comprising," when used in this specification, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof. It will be understood that when an element is referred to as being "connected" or "coupled" to another element, it can be directly connected or coupled to the other element or intervening elements may also be present. Further, "connected" or "coupled" as used herein may include wirelessly connected or wirelessly coupled. As used herein, the term "and/or" includes all or any element and all combinations of one or more of the associated listed items.

It will be understood by those skilled in the art that, unless otherwise defined, all terms (including technical and scientific terms) used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. It will be further understood that terms, such as those defined in commonly used dictionaries, should be interpreted as having a meaning that is consistent with their meaning in the context of the prior art and will not be interpreted in an idealized or overly formal sense unless expressly so defined herein.

The invention provides a drilling measuring and controlling mechanism which is used for determining the drilling position on a pull rod and guiding the drilling to drill accurately. To facilitate the disclosure of the drilling control mechanism of the present invention, the invention is now disclosed in connection with a drilling bench, specifically:

the invention provides a drilling workbench 100, the drilling workbench 100 is used for drilling a pull rod 14 of an antenna, the drilling workbench 100 is simple to operate, and the pull rod 14 can be stably limited so as to facilitate accurate drilling. The pull rods are used as phase shifting parts of phase shifters in the antenna, and generally, each pull rod is used for linking one or more phase shifters adopted in radiation unit columns of the same frequency band.

In an exemplary embodiment of the present invention, referring to fig. 1, the drilling platform 100 includes a base 12, a clamping mechanism 1, a drilling control mechanism 3, and a pressure control mechanism 2.

The base 12 includes a bottom plate 122 and a pair of side walls erected on two sides of the bottom plate 122, and the bottom plate 122 and the pair of side walls form a groove structure for mounting the clamping mechanism 1, the drilling measurement and control mechanism 3, and the pressure control mechanism 2. The pair of sidewalls are a first sidewall 121 and a second sidewall 123, respectively, and the first sidewall 121 and the second sidewall 123 both extend along the longitudinal direction of the bottom plate 122 and are parallel to each other.

Referring to fig. 2, the clamping mechanism 1 includes a bracket 18, a lever bracket 17, a pair of positioning plates 80, a link assembly 19, and a locking member.

The support 18 includes a base plate 55 and a plurality of pairs of support plates 58, each pair of support plates 58 is respectively vertically disposed on two sides of the base plate 55 in the length direction, and are parallel and symmetrical to each other, in this embodiment, the plurality of pairs of support plates 58 are uniformly disposed on two sides of the base plate 55. The substrate 55 is disposed on the bottom plate 122, and the substrate 55 extends along the longitudinal direction of the base 12. Therefore, a smaller groove is formed between the base plate 55 and the plurality of pairs of supporting plates 58 relative to the base 12 for accommodating other components.

With reference to fig. 3 to 6, the connecting rod assembly 19 comprises a sliding rod 191, two oscillating rods 192 and two connecting blocks 193; the two swing levers 192 are referred to as a first swing lever 1921 and a second swing lever 1922, respectively; the two connecting blocks 193 are referred to as a first connecting block 1931 and a second connecting block 1932, respectively.

Referring to fig. 7, one end of the sliding rod 191 is inserted into the base plate 55, the base plate 55 is provided with a through hole 74 corresponding to the sliding rod 191, the oilless bushing 20 is provided at the through hole 74, one end of the sliding rod 191 is connected to the base plate 55 by inserting the oilless bushing 20, and the sliding rod 191 is movable up and down (in the thickness direction of the bottom plate 122) by the action of the oilless bushing 20. The sliding rod 191 may further penetrate into the bottom plate 122 of the base 12, and correspondingly, a slot hole for the sliding rod 191 to go through is formed in the bottom plate 122, so that the connecting rod assembly 19 can go up and down with respect to the base 12 and the base plate 55.

The other end of the slide rod 191 is provided with a pivot hole 197, the pivot hole 197 is penetratingly provided in a radial direction of the slide rod 191, and the slide rod 191 is provided with a pivot plane 77 with respect to two through openings of the pivot hole 197 for avoiding the swing lever 192.

The link assembly 19 further includes a pivot shaft 194, the pivot shaft 194 is disposed through the pivot hole 197, and two ends of the pivot shaft 194 respectively extend out of the pivot hole 197.

Both ends of the swing lever 192 are provided with through holes penetrating through the thickness direction thereof, and the two through holes are the first through hole 75 and the second through hole 76, respectively. One end of the pivot shaft 194 penetrates through the first through hole 75 of the swing lever 192, the pivot shaft 194 is in clearance fit with the first through hole 75, after the pivot shaft 194 penetrates through the first through hole 75 of the swing lever 192, the swing lever 192 can rotate relative to the pivot shaft 194, in order to prevent the swing lever 192 from sliding off the pivot shaft 194, a snap ring 195 used for restricting the swing lever 192 from moving along the axial direction of the pivot shaft 194 can be arranged on the end portion of the pivot shaft 194, an oil-free bushing 196 is further arranged on the first through hole 75 of the swing lever 192, and the pivot shaft 194 is sleeved with the oil-free bushing 196.

Two ends of the pivot shaft 194 are respectively inserted into the first through holes 75 of the two swing levers 192, that is, two ends of the pivot shaft 194 are respectively connected to the first through holes 75 of the first swing lever 1921 and the first through holes 75 of the second swing lever 1922, so that both the two swing levers 192 can rotate relative to the pivot shaft 194.

One end of the connecting block 193 is provided with a through hole 78 penetrating through the thickness direction of the connecting block 193, the through hole 78 of the connecting block 193 corresponds to the second through hole 76 of the swing rod 192 and is also connected in the two through holes in a penetrating manner through a pivot shaft 194, the pivot shaft 194 is in clearance fit with the two through holes respectively, so that the connecting block 193 and the swing rod 192 can rotate relatively, in order to prevent the connecting block 193 and the swing rod 192 from sliding off the pivot shaft 194, snap rings 195 used for limiting the transverse movement of the connecting block 193 and the swing rod 192 are arranged at two end parts of the pivot shaft 194, oil-free bushings 196 are arranged at the through holes of the connecting block 193 and the second through holes 76 of the swing rod 192, and the pivot shaft penetrates through the oil-free bushings. The two swing levers 192 are each connected to the two link blocks 193 by one pivot shaft 194, and specifically, the first swing lever 1921 is connected to the first link block 1931 by one pivot shaft 194, and the second swing lever 1922 is connected to the second link block 1932 by one pivot shaft 194.

The connecting block 193 is further provided with a connecting hole 61 opened along the transverse direction of the bottom plate 122. The positioning plate 80 is provided with a through hole 62 formed along the transverse direction of the bottom plate 122. The through hole 62 of the positioning plate 80 corresponds to the connecting hole 61 of the connecting block 193, and the through hole 62 of the positioning plate 80 and the connecting hole 61 of the connecting block 193 can be fixedly connected through a connecting shaft. In the longitudinal direction, the connecting block 193 and the positioning plate 80 may be provided with a plurality of sets of corresponding connecting holes 61 and through holes so as to cooperate with each other at a plurality of positions in the longitudinal direction to support the positioning plate 80 in a balanced manner.

Referring to fig. 2 and 7, the pair of positioning plates 80 are respectively a first positioning plate 15 and a second positioning plate 16, the first positioning plate 15 is fixedly connected with the first connecting block 1931 through a connecting shaft, and the second positioning plate 16 is fixedly connected with the first connecting block 1931 through a connecting shaft.

The positioning plates 80 extend along the longitudinal direction of the bottom plate 122, and the pair of positioning plates 80 are parallel and symmetrical to each other.

The positioning plate 80 is further provided with a shaft hole 60 extending through the positioning plate 80 along the transverse direction of the bottom plate 122, so that two positioning plates 80 respectively form one shaft hole 60, and the shaft holes 60 on the two positioning plates 80 have the same size and are located on the same axis. The two positioning plates 80 are disposed in the space formed between each pair of the support plates 58.

Referring to fig. 2 and 8, each pair of support plates 58 of the bracket 18 is provided with a locking hole 63, and the locking holes 63 of each pair of support plates 58 have the same size and are located on the same axis. The locking holes 63 of each pair of support plates 58 are disposed on the same axis as the shaft holes 60 of the two positioning plates 80. The pair of support plates 58 are respectively assumed to be the first support plate 56 and the second support plate 57.

The locking member includes a locking shaft 22, and the locking shaft 22 penetrates through each locking hole 63 of the two support plates 58 and each shaft hole 60 of the two positioning plates 80, so as to dispose the two positioning plates 80 on the bracket 18. And the oil-free bush 21 for facilitating the sliding of the locking shaft 22 is arranged on each locking hole 63 and the shaft hole. The locking shaft 22 is in the form of a stud, and a snap ring 23 is clamped at the end of the locking shaft 22 not having a nut to prevent the locking shaft 22 from moving in the axial direction.

Specifically, the locking shaft 22 passes through the locking hole 63 of the first support plate 56, the shaft hole of the first positioning plate 15, the shaft hole of the second support plate 57, and the locking hole 63 of the second support plate 57 in this order. The first positioning plate 15 and the second positioning plate 16 can move relatively through the locking shaft 22, and the locking shaft 22 has a guiding function, so that the first positioning plate 15 and the second positioning plate 16 only move relatively along the axial direction of the locking shaft 22, and the first positioning plate 15 and the second positioning plate 16 are prevented from moving in other directions.

With reference to fig. 9 to 11, the pull rod supporting plate 17 extends along the longitudinal direction of the bottom plate 122, and the pull rod supporting plate 17 is disposed between the first positioning plate 15 and the second positioning plate 16. The pull rod supporting plate 17 comprises a longitudinal portion 172 and a plurality of supporting feet 173 arranged below the longitudinal portion 172, a positioning groove 171 is formed in an opening on a top surface (17 facing the same direction as the bottom plate 122) of the longitudinal portion 172, the positioning groove 171 is a through groove formed in the longitudinal direction of the bottom plate 122, so that the longitudinal portion 172 is divided into two side walls at the positioning groove 171, the top surfaces of the two side walls form a flat supporting surface 71 for placing the pull rod 14 of the antenna, and the positioning groove 171 is used for receiving debris generated during processing of the pull rod 14. The plurality of support feet 173 are each coupled to the base plate 55 of the frame 18 to support the elongated portion 172, and the support feet 173 are not disposed with the linkage assembly 19 to prevent the support feet 173 from blocking movement between the components of the linkage assembly 19.

The height of the supporting surface 71 is lower than the height of the top surface 72 of the positioning plate 80, and preferably, the height difference between the height of the supporting surface 71 and the height of the top surface 72 of the positioning plate 80 is slightly smaller than the thickness of the pull rod 14 (the thickness direction of the pull rod 14 is the same as the height direction of the positioning plate 80).

Since the tie bar supporting plate 17 is disposed between the first positioning plate 15 and the second positioning plate 16, the first positioning plate 15 and the second positioning plate 16 can be relatively close to clamp the tie bar supporting plate 17, and the supporting surface 71 for the tie bar supporting plate 17 is located at a height lower than the top surface 72 of the positioning plate 80. When the pull rod 14 is placed on the two supporting surfaces 71 of the pull rod supporting plate 17, the pull rod 14 can be clamped by the first positioning plate 15 and the second positioning plate 16, so that the pull rod 14 does not move laterally. In order that the first positioning plate 15 and the second positioning plate 16 can clamp the pull rod 14 so that the pull rod 14 does not move laterally, referring to fig. 8, a locking spring 24 may be provided between the positioning plate 80 and the support plate 58, and the first positioning plate 15 and the second positioning plate 16 can clamp the pull rod 14 under the spring force of the locking spring 24.

Specifically, a locking spring 24 is disposed between the first positioning plate 15 and the first supporting plate 56, such that the locking spring 24 is compressed between the first positioning plate 15 and the first supporting plate 56, and the locking spring 24 exerts a force on the first positioning plate 15 in a direction toward the second positioning plate 16; a locking spring 24 is arranged between the second positioning plate 16 and the second supporting plate 57, so that the locking spring 24 is in a compressed state between the second positioning plate 16 and the second supporting plate 57, and the locking spring 24 exerts an acting force on the second positioning plate 16 in a direction towards the first positioning plate 15; thereby, the first positioning plate 15 and the second positioning plate 16 are forced to face each other, and the first positioning plate 15 and the second positioning plate 16 can clamp the pull rod 14.

In one embodiment, referring to fig. 9, the thickness of the pull rod 14 is greater than the height difference between the height of the supporting surface 71 and the height of the top surface 72 of the positioning plate 80, so as to facilitate the placement of the pull rod 14 on the two supporting surfaces 71 of the pull rod supporting plate 17 tightly clamped by the first positioning plate 15 and the second positioning plate 16, a first guide surface 151 is provided between the top surface of the first positioning plate 15 and the side wall of the first positioning plate 15 facing the second positioning plate 16, a second guide surface 161 is formed between the top surface of the second positioning plate 16 and the side wall of the second positioning plate 16 facing the first positioning plate 15, by providing a guide surface on each of the first positioning plate 15 and the second positioning plate 16, the tie rod 14 having a thickness greater than the height difference between the height of the support surface 71 and the height of the top surface 72 of the positioning plate 80 can be placed on the two support surfaces 71 of the tie rod support plate 17 along the guide surfaces.

In order to adapt to the pull rods 14 with different specifications, that is, the pull rods 14 with different thicknesses and widths, the pull rod supporting plate 17 with the same specification can be correspondingly used or the distance between the first positioning plate 15 and the second positioning plate 16 can be changed.

When the width of the pull rod 14 processed later is greater than the width of the pull rod 14 processed previously, the pull rod 14 with a greater width can be disposed on the two supporting surfaces 71 of the pull rod support plate 17 by adjusting the distance between the first positioning plate 15 and the second positioning plate 16. Specifically, the first positioning plate 15 and the second positioning plate 16 are moved in opposite directions along the locking shaft 22, that is, the first positioning plate 15 is moved toward the first support plate 56, and the second positioning plate 16 is moved toward the second support plate 57; the first positioning plate 15 will sequentially drive the first connecting block 1931 to move towards the first supporting plate 56, and the second positioning plate 16 will drive the second connecting block 1932 to move towards the second supporting plate 57; the first connecting block 1931 will drive the first oscillating rod 1921 to move toward the first supporting plate 56, and the second connecting block 1932 will drive the second oscillating rod 1922 to move toward the second supporting plate 57; so that the angle between the first and second swinging rods 1921 and 1922 is increased, and in order to increase the angle between the first and second swinging rods 1921 and 1922, the first and second swinging rods 1921 and 1922 will drive the sliding rod 191 to move upward.

Thereby, an increase in the spacing between the first positioning plate 15 and the second positioning plate 16 is achieved. When the pull rod 14 with a smaller width is replaced, the manner of reducing the distance between the first positioning plate 15 and the second positioning plate 16 can be referred to the manner of increasing the distance between the first positioning plate 15 and the second positioning plate 16, and the specific principle can be analogized, and further description is omitted here for brevity.

In an exemplary embodiment of the present invention, the drilling platform 100 may include a plurality of clamping mechanisms 1 as described above, and the plurality of clamping mechanisms 1 constitute a clamping system to clamp and fix a pull rod 14 having a certain length, so that the pull rod 14 does not move transversely in the length direction thereof. The plurality of clamping mechanisms 1 share the same pull rod supporting plate 17, first positioning plate 15 and second positioning plate 16. The plurality of clamping mechanisms 1 are uniformly arranged along the same axis at intervals and are used for fixing different length positions of the clamping pull rod 14 respectively.

In one embodiment, referring to fig. 12, a reference member 13 is further provided at the end of the tie bar support 17 of the clamping system, the reference member 13 being used to limit the movement of the tie bar 14 along its length to prevent the tie bar 14 from sliding out of the clamping system from its length. Specifically, the reference member 13 includes a reference portion including a reference surface 131 opposed to an end surface of one end in the longitudinal direction of the pull rod 14, the reference surface 131 serving to prevent the pull rod 14 from moving in the longitudinal direction thereof. Therefore, the reference member 13 faces the positioning groove 171, and in order to prevent the reference member 13 from blocking the positioning groove 171 to discharge chips, the reference member 13 is provided with a chip discharge port 132 corresponding to the positioning groove 171, so that the chips in the positioning groove 171 can be discharged from the positioning groove 171. The reference member 13 is fixed to the tie bar support plate 17 by screwing the tie bar support plate 17. Preferably, one reference piece 13 is provided at each end of the tie bar carrier 17.

In the exemplary embodiment of the present invention, the pressure control mechanism 2 is used to restrict the up-down movement of the restricting link 14. Referring to fig. 1, the pressure control mechanism 2 includes a guide rail and a pressure control device.

The guide rail is referred to as a first guide rail 7, the first guide rail 7 is disposed on the top surface of the first side wall 121, and the first guide rail 7 extends along the length direction of the first side wall 121. The end parts of the two ends of the first guide rail 7 are respectively provided with a stop block 4 for stopping the pressure control device from sliding out of the first guide rail 7.

Referring to fig. 13 and 14, the pressure control device includes a slider (the slider is referred to as a first slider 8), a pressure roller 31, a mounting seat 27, a spiral knob 25, a pressure lever 28, and a fastening spring 33.

The first slider 8 is disposed on the first guide rail 7, and the first slider 8 can slide along the length direction of the first guide rail 7.

One end of the mounting seat 27 is disposed on the first sliding block 8, and the first sliding block 8 can drive the mounting seat 27 to slide along the first guide rail 7. The other end of the mounting seat 27 is provided with a mounting portion 271, a cavity (referred to as a mounting cavity 283) is formed in the mounting portion 271, and the mounting cavity 283 has an opening facing the bottom plate 122. In the exemplary embodiment of the present invention, the mounting well 283 is a square shaped cavity having an opening facing the bottom plate 122.

One end of the pressing rod 28 extends into the installation cavity 283 to move up and down in the installation cavity 283, in order to prevent the pressing rod 28 from sliding off the installation cavity 283, a clamping sliding portion 281 is arranged at the end of the pressing rod 28, a clamping portion 272 is arranged at the opening of the installation cavity 283, and the clamping sliding portion 281 and the clamping portion 272 are mutually matched, so that the pressing rod 28 can slide up and down along the installation cavity 283.

The other end of the pressure bar 28 is provided with an opening, so that the end is bifurcated, the opening divides the end into two pressure bar strips 282, and two opposite shaft holes are provided on the two pressure bar strips 282, and the two shaft holes have the same size and are located on the same axis.

The pressing wheel 31 is disposed between the two pressing bars 282, and a rotating hole is disposed on the pressing wheel 31 and corresponds to each of the shaft holes of the two pressing bars 282. The rotating hole and the two shaft holes are formed in the bolt 29 in a penetrating mode, and the pressing wheel 31 rotates relative to the rotating shaft. A spacer bush 34 is further arranged at the rotating hole of the pressing wheel 31, and the bolt 29 penetrates through the rotating hole through the inserting spacer bush 34. The end of the bolt 29 not having a nut is snap-fitted with a snap ring 30 to prevent the bolt 29 from slipping out of the rotation hole and the two shaft holes. In one embodiment, puck 31 is preferably a deep groove ball bearing puck 31.

Referring to fig. 15, the pressing wheel 31 is used for pressing and connecting the pull rod 14 disposed on the pull rod supporting plate 17, and the length of the mounting seat 27 is adjusted so that the pressing wheel 31 can be opposite to the positioning groove 171 of the support plate of the pressing rod 28, so as to press and connect the pull rod 14 disposed on the support plate of the pressing rod 28, and the pressing wheel 31 is pressed and connected with the pull rod 14, so as to restrict the up-and-down movement of the pull rod 14.

The fastening spring 33 is disposed in the mounting cavity 283 and is disposed along the axial direction of the mounting cavity 283, one end of the fastening spring 33 is connected to the engaging sliding portion 281 of the pressing rod 28, and the up-and-down movement of the pressing rod 28 is controlled by controlling the compression amount of the fastening spring 33.

A threaded hole is formed in the top surface (the surface facing the bottom plate 122) of the mounting portion 271, the threaded hole extends into the mounting cavity 283, and the axial direction of the mounting cavity 283 is the same as the extending direction of the threaded hole. One end of the spiral knob 25 is a knob, the other end is a screw, the screw corresponds to the threaded hole of the mounting portion 271, the screw can extend into the mounting cavity 283, a spring adjusting plate 32 is further arranged at one end of the screw, the spring adjusting plate 32 is connected with one end of the fastening spring 33, which is not connected with the compression rod 28, and the spring adjusting plate 32 is used for controlling the compression amount of the fastening spring 33 and further controlling the up-and-down movement of the compression rod 28.

Specifically, the screw knob 25 is rotated to move towards the installation cavity 283 to drive the spring adjusting plate 32 arranged on the screw rod to move towards the compression rod 28, and the spring adjusting plate 32 compresses the fastening spring 33, so that the compression wheel 31 is stressed to press the upper pull rod 14 of the compression rod 28 supporting plate; the knob screw 25 moves towards the direction far away from the installation cavity 283 to drive the spring adjusting plate 32 arranged on the screw to move towards the direction far away from the installation cavity 283, the spring adjusting plate 32 releases the fastening spring 33, and the up-and-down position of the pull rod 14 on the support plate of the press rod 28 is adjusted.

In one embodiment, to facilitate mounting of the fastening spring 33 and the plunger 28, an opening is also formed on the other side of the mounting cavity 283 opposite to the opening, and the upper cover 26 is used to enclose the opening to facilitate mounting of the fastening spring 33 and the plunger 28.

The pressure control device can slide along the first guide rail 7, and press the pull rod 14 on the pull rod supporting plate 17 through the pressure wheel 31 to restrict and limit the up-and-down movement of the pull rod 14. Specifically, the height of pressure wheel 31 relative to base plate 122 at the point 311 of application of force to tension rod 14 is lower than the height of upper surface 141 of tension rod 14 relative to base plate 122, thereby allowing pressure wheel 31 to compress tension rod 14.

In an exemplary embodiment of the present invention, referring to fig. 1, the drilling platform 100 may include a plurality of pressure control mechanisms 2 as described above, and the plurality of pressure control mechanisms 2 form a pressure control system to press each portion of the pull rod 14, so that the pull rod 14 is controlled by the pressure control system at a plurality of positions in the length direction thereof, and the pull rod 14 is restrained from moving up and down and is straightened as a whole.

Specifically, a plurality of pressure lever mechanisms of the pressure control system share the same first guide rail 7, a plurality of pressure lever 28 mechanisms can slide on the first guide rail 7, and can be uniformly arranged on the first guide rail 7 at intervals by adjusting the distance between the pressure lever mechanisms in use, and the pressing wheels 31 of the plurality of pressure lever mechanisms are all opposite to the positioning grooves 171 of the support plates of the pressure levers 28 to respectively press and connect different parts in the extending direction of the pull rod 14.

In an exemplary embodiment of the present invention, referring to fig. 1, the drilling control mechanism 3 includes a guide rail (referred to as the second guide rail 52) and a drilling table 66.

The second rail 52 is disposed on the top surface of the second sidewall 123, and the second rail 52 extends along the length direction of the second sidewall 123. Stoppers 4 are provided at both end portions of the second guide rail 52, respectively, for preventing the drill table 66 from slipping off the second guide rail 52.

Referring to fig. 16, the drilling table 66 includes a mounting plate 39, a short rail 38, a placing plate 36, a drill guide 35, and a slider (referred to as a second slider 53).

The second sliding block 53 is disposed on the second guide rail 52 and can slide along the length direction of the second guide rail 52, and the second sliding block 53 drives the drilling table 66 to slide along the length direction of the second guide rail 52.

The mounting plate 39 includes a support portion 392 and a limiting portion 391 connected to each other. The second sliding block 53 is arranged at the bottom of the limiting part 391, and the second sliding block 53 drives the drilling platform 66 to move by driving the mounting plate 39.

The end of the position-limiting part 391 not connected to the support part 392 is further provided with a threaded hole penetrating the position-limiting part 391, and the threaded hole is used for installing the screw knob 50. The screw knob 50 comprises a knob and a screw connected with the knob, the screw faces the second side wall 123, the screw can be driven to move towards the second side wall 123 by rotating the knob of the screw knob 50, when the screw is fixedly connected with the second side wall 123 in a contact manner, the screw knob 50 enables the second sliding block 53 to be limited relatively, and the second sliding block 53 is fixed at a certain position on the second guide rail 52 and can not slide relative to the second guide rail 52 any more.

The short guide rail 38 is disposed on the support portion 392, the length of the short guide rail 38 is equal to or less than the length of the support portion 392, the two ends of the short guide rail 38 are both provided with the stoppers 4, and the extending direction of the short guide rail 38 is perpendicular to the longitudinal direction of the bottom plate 122.

The short guide rail 38 is provided with a slide block (called a third slide block 51) sliding relative to the short guide rail 38, and the third slide block 51 slides on the short guide rail 38 and is limited by the stoppers 4 at the two ends of the short guide rail 38, so that the third slide block 51 cannot slide out of the guide range of the short guide rail 38.

The placing plate 36 is disposed above the third sliding block 51, and the third sliding block 51 can drive the mounting plate 39 to move the placing plate 36 towards the transverse direction of the bottom plate 122 when sliding on the short guide rail 38, that is, the third sliding block 51 drives the mounting plate 39 to extend the placing plate 36 towards the pull rod support plate 17. The mounting plate 39 has a mounting hole 354 formed at one end thereof extending in the direction of the drawbar pallet 17, the mounting hole 354 penetrating the mounting plate 36 of the mounting plate 39 in the direction of the bottom plate 122, and the mounting hole 354 facing the positioning groove 171 of the drawbar pallet 17.

Referring to fig. 17 and 18, the drill guide 35 is in the form of a sleeve and is disposed in the placement hole 354. The drill guide 35 is provided with a through hole 353, and an end of the drill guide 35 not facing the positioning groove 171 of the drawbar pallet 17 is provided with a guide opening 351, a diameter of the guide opening 351 is larger than a diameter of the through hole 353, and the guide opening 351 is transitionally connected with the through hole 353 so that the drill 6 inserted into the through hole 353 of the drill guide 35 can be guided by the guide opening 351. In order to facilitate the placement of the drill guide 35 in the placement hole 354 or the removal of the drill guide 35 from the placement hole 354, a carrying notch 352 is provided on the outer side of the drill guide 35, and the carrying notch 352 prevents the drill guide 35 from falling through the placement hole 354.

In fig. 19, the mounting plate 39 and the support 392 of the placement plate 36 are also provided with corresponding pin holes, and the pin hole supports 392 of the mounting plate 39 and the placement plate 36 are the same in size, and at the position where they are aligned, the two pin holes have the same virtual central axis, and the virtual central axis is perpendicular to the support 392 in the extending direction of the short guide rail 38. When the mounting plate 39 and the placing plate 36 are aligned with the central axes of the latch hole supports 392 of each other, the latches 37 may be used to penetrate the latch hole supports 392 of each of the mounting plate 39 and the placing plate 36 so that the mounting plate 39 remains fixed in a certain position.

In an exemplary embodiment of the present invention, when the pull rod 14 is disposed on the supporting surface 71 of the pull rod supporting plate 17, after the clamping system composed of the plurality of clamping mechanisms 1 laterally constrains and limits the pull rod 14, and after the pressure control system composed of the plurality of pressure control mechanisms 2 vertically constrains and limits the pull rod 14, a specific drilling position on the pull rod 14 can be determined by the drilling measurement and control mechanism 3.

Specifically, the drilling position of the tie bar 14 can be decomposed into a longitudinal drilling position and a transverse drilling position on the planar coordinate system in the horizontal plane, wherein for a hole to be drilled on the tie bar, the longitudinal drilling position corresponds to the position of the hole in the longitudinal direction of the tie bar 14, and the transverse drilling position corresponds to the position of the hole in the transverse direction of the tie bar 14.

Therefore, the pull rod 14 is disposed on the pull rod supporting plate 17, and the longitudinal direction of the pull rod 14 is parallel to the longitudinal direction of the bottom plate 122. Therefore, after the specific position of the hole position in the longitudinal direction of the pull rod 14 is determined, the second sliding block 53 is moved to slide on the second guide rail 52, so as to drive the drilling table 66 to slide on the second guide rail 52 and move to the drilling position corresponding to the specific position, and when the drilling table 66 moves to the drilling position, the screw knob 50 can be used for limiting, so that the second sliding block 53 is fixed at the position.

Since the length direction of the short guide rail 38 is perpendicular to the length direction of the bottom plate 122, the third slider 51 is moved to drive the placing plate 36 to move towards the pull rod supporting plate 17, when the through hole 353 of the drilling guide 35 on the placing plate 36 faces the specific position of the hole of the pull rod, the transverse drilling position of the through hole on the coordinate system is determined, the third slider 51 stops sliding, and the mounting plate 39 and the placing plate 36 are fixed by inserting a bolt through the mounting plate 39 and the bolt hole supporting part 392 on the placing plate 36. And, since the drilling position in the longitudinal direction has been moved by the second slider 53, when the drilling position in the lateral direction is moved by the third slider 51, the position where the draw bar 14 is to be drilled is reached.

In the present embodiment, the pull rod 14 is drilled by means of manual drilling. Because the through hole 353 of the drilling guide 35 is over against the opening position of the pull rod 14, the drill bit 6 of the pistol drill 5 can be inserted into the through hole 353, and the through hole 353 of the drilling guide 35 limits the drill bit 6, so that the hole at the corresponding position can be drilled on the pull rod 14, and the hole can not be drilled eccentrically due to the fact that the through hole 353 of the drilling guide 35 is not limited.

In one embodiment, to facilitate accurate determination of the specific position of the opening of the drawbar in the longitudinal direction, a fourth rail 10 may be provided on the outside of the second side wall 123, the fourth rail 10 being parallel to the second rail 52, and a scale may be provided on the fourth rail 10. A fourth slider 11 is disposed at one end of the limiting portion 391, the fourth slider 11 is matched with the fourth guide rail 10, and the fourth slider 11 can slide on the fourth guide rail 10. In order to accurately determine the drilling position in the longitudinal direction, the fourth slider 11 is designed into a vernier caliper head shape, so that the vernier caliper head-shaped fourth slider 11 and the graduated scale arranged on the fourth guide rail 10 are matched to form a vernier caliper, and the position of the drilling position in the specific longitudinal direction can be accurately determined.

In another embodiment, the fourth guiding rail may be designed as a guiding strip, and the fourth sliding block may be designed to slide along the guiding strip.

In another embodiment, in conjunction with fig. 20 and 21, the borehole survey control mechanism 3 further comprises a drill 4128.

The drilling table 66 is also provided with a stroke plate 4123 erected on the placing plate 36, and the stroke plate 4123 is provided with a sliding table cylinder 4124 arranged along the longitudinal direction thereof.

A transition plate 4125 is arranged on one side of the sliding table cylinder 4124, which is not connected with the stroke plate 4123, and the sliding table cylinder 4124 can drive the transition plate 4125 to move up and down.

The side of the transition plate 4125, which is not connected to the stroke plate 4123, is provided with a rotary cylinder 4126, and a drilling machine 4128 is provided on the rotary cylinder 4126, and the rotary cylinder 4126 can drive the drilling machine 4128 to rotate at 360 degrees.

The drilling machine 4128 includes two drill bits, and the selection drill bit can be rotated by controlling the rotating cylinder 4126.

Specifically, by providing the drilling machine 4128 on the drilling measurement and control mechanism 3, manual drilling can be avoided. The central axis of the drill 4129 of the drilling machine 4128 is the same as the central axis of the through hole of the drill guide 35, so that the drill 4129 of the drilling machine 4128 can extend into the through hole of the drill guide 35 to drill the drawbar 14 provided on the drawbar supporter 17.

The specific drilling by the drilling machine 4128 is arranged such that, after the drilling position on the drawbar 14 is determined by the drilling table 66, the corresponding drill 4129 is selected by controlling the rotation of the rotary cylinder 4126. After the selection of the drill 4129 is completed, the sliding table cylinder 4124 is controlled to slide to sequentially drive the transition plate 4125, the rotary cylinder 4126 and the drilling machine 4128 to move towards the direction of the bottom plate 122, so that the drill 4129 of the drilling machine 4128 extends into the through hole of the drilling guide 35, and the sliding table cylinder 4124 is continuously controlled to slide towards the direction of the bottom plate 122 until the drill 4129 is in contact with the pull rod 14 to drill a hole on the pull rod 14. Thereby, the purpose of drilling the draw bar 14 by the drill 4128 is achieved.

In one embodiment, referring to fig. 22, the second rail 52 has a rack 54 at the bottom, and the second slider 53 has a corresponding rack corresponding to the rack 54 at the bottom of the second rail 52, so that the second slider 53 is driven by electricity to move by the mutual engagement of the racks. The second slider 53 may be driven by a transmission device such as a motor or a cylinder.

In one embodiment, the drilling table 66 is not provided with a short guide rail, and the placing plate 36 is moved by the sliding table cylinder 4122 to move towards the draw bar support plate 17, so as to drive the drilling machine 4128 to move.

In one embodiment, the drilling measurement and control mechanism 3 is further provided with a control circuit for controlling the operation of the electrical components.

In one embodiment, a stroke sensor switch or a cylinder sensor switch 41212 is provided on each slide rail, each slider, and each cylinder for detecting the amount of movement of these moving mechanisms.

In summary, the drilling platform of the drilling measurement and control mechanism of the present invention can move along the longitudinal direction of the guide rail on the guide rail, and the drilling platform can move along the transverse direction of the guide rail, so that the specific drilling position on the drilling surface of the pull rod can be determined.

The foregoing description is only exemplary of the preferred embodiments of the invention and is illustrative of the principles of the technology employed. It will be appreciated by those skilled in the art that the scope of the invention according to the present invention is not limited to the specific combination of the above-mentioned features, but also encompasses other embodiments in which any combination of the above-mentioned features or their equivalents is possible without departing from the scope of the invention as defined by the appended claims. For example, the above features and (but not limited to) features having similar functions of the present invention are mutually replaced to form the technical solution.

Although the subject matter has been described in language specific to structural features and/or methodological acts, it is to be understood that the subject matter defined in the appended claims is not necessarily limited to the specific features or acts described above. Rather, the specific features and acts described above are disclosed as example forms of implementing the claims.

Claims (10)

1. A drilling workbench comprises a base, a clamping mechanism, a drilling measurement and control mechanism and a pressure control mechanism, wherein the drilling measurement and control mechanism is arranged on the base, the base is provided with a bottom plate, a pair of side walls are vertically arranged on two sides of the bottom plate to define a longitudinal groove, the clamping mechanism is arranged on the base and arranged along the longitudinal direction of the groove, and a pull rod supporting plate for accommodating a workpiece is provided; it is characterized in that the drilling measurement and control mechanism comprises:

the guide rail is arranged above the side wall of the base;

the drilling platform comprises a mounting plate, a short guide rail fixed on the mounting plate and extending along the transverse direction of the base, and a placing plate which is slidably arranged on the short guide rail to provide a guide hole, so that the guide hole can be aligned with a workpiece on the pull rod supporting plate;

the fixture includes:

the pair of positioning plates are arranged in parallel and are arranged at two sides of the pull rod supporting plate;

the connecting rod assembly is connected with the pair of positioning plates respectively to control the opening and closing of the pair of positioning plates and comprises a sliding rod, swinging rods and connecting blocks, one end of the sliding rod is arranged on the base plate in a liftable mode, the other end of the sliding rod penetrates through a pivoting shaft which is radially arranged on the base plate, two ends of the pivoting shaft are respectively pivoted with one ends of the two swinging rods, the other ends of the two swinging rods respectively correspond to the two connecting blocks which are pivoted, and the two connecting blocks are locked with the two positioning plates.

2. The drilling station of claim 1, further comprising a screw knob for locking the mounting plate to the base to restrict travel on the rail.

3. The drilling table of claim 1, wherein the pair of side walls includes a first side wall and a second side wall, the first side wall being provided on an outer side thereof with a scale extending lengthwise, the drilling table being provided on respective sides with markers indicating scales on the scale.

4. The drilling table of claim 1, further comprising a locking bolt for locking the placement plate to the short rail to limit sliding of the placement plate on the short rail.

5. The drilling table of claim 1, wherein the mounting plate is further provided at a bottom thereof with a slider for sliding on the guide rail.

6. The drilling table of claim 1, further comprising a drill guide, the guide hole being provided on the drill guide, and the placement plate being provided with a placement hole for mounting the drill guide.

7. A drilling platform as claimed in claim 6, wherein the drill guide is provided with a through-hole therethrough for the passage of a drill bit, the through-hole being provided at one end with a pilot port for guiding the drill bit.

8. The drilling station of any one of claims 1 to 7, wherein the drilling measurement control mechanism further comprises a drilling machine disposed on the placing plate.

9. The drilling table of claim 8, wherein the drilling table comprises a stroke plate vertically disposed on the placing plate and a sliding table cylinder disposed on the stroke plate for driving the drilling machine to slide up and down.

10. The drilling station of claim 9, wherein the drilling station includes a rotary cylinder disposed on one side of the slide cylinder, the rotary cylinder driving the drill to rotate.

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