CN114083647A

CN114083647A - Manufacturing mold for building engineering concrete prefabricated laminated slab and using method thereof

Info

Publication number: CN114083647A
Application number: CN202111364423.8A
Authority: CN
Inventors: 广家成
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-11-17
Filing date: 2021-11-17
Publication date: 2022-02-25

Abstract

The invention relates to a mold for manufacturing a constructional engineering concrete prefabricated laminated slab and a using method thereof. The invention can solve the problems that the existing building engineering concrete prefabricated composite floor slab needs to be spliced by manpower during the concrete pouring, the position of the steel bar extending out of the template needs to be blocked, the quantity of the steel bars extending out of the composite slab is large, the operation of blocking the steel bars extending out of the template one by one is complex, the consumed time is long, the spliced templates need to be dismantled one by one during the demoulding of the formed composite slab, the damage to the surface of the composite slab is uniformly caused by the manual work during the template dismantling, and the damaged composite slab after the demoulding needs to be repaired.

Description

Manufacturing mold for building engineering concrete prefabricated laminated slab and using method thereof

Technical Field

The invention relates to the technical field of building prefabricated parts, in particular to a manufacturing mold of a building engineering concrete prefabricated laminated slab and a using method thereof.

Background

The prefabricated concrete member is used for construction in the construction process of building engineering, the construction difficulty can be reduced, the integrity of the laminated floor slab is good, the upper surface and the lower surface of the slab are smooth, decoration of a finish coat is facilitated, the prefabricated slab is suitable for high-rise buildings and large-bay buildings with high integral rigidity requirements, the prefabricated slab and the cast-in-place reinforced concrete layer are laminated to form the assembled integral floor slab, reinforcing steel bars are tied up according to requirements in the manufacturing process of the laminated slab and then placed in a mold to be poured with concrete to form a plate structure, and the reinforcing steel bars of the formed laminated slab extend to the outer side of the concrete structure.

However, the following problem that exists in the preparation process of current prefabricated composite floor slab of building engineering concrete, need artifical template to the cast concrete to splice when the cast concrete, need stretch out the position of template to the reinforcing bar and carry out the shutoff, and the reinforcing bar that extends on the superimposed sheet is in large quantity, it is complicated to carry out the shutoff operation to the reinforcing bar that stretches out the template one by one, it is long to consume time, and the superimposed sheet after the shaping needs to demolish the template of concatenation one by one when the drawing of patterns, the manual work leads to the superimposed sheet surface damage in unison when dismantling the template, need restore the superimposed sheet damaged after the drawing of patterns.

Disclosure of Invention

The invention provides a mold for manufacturing a building engineering concrete prefabricated laminated slab and a using method thereof, aiming at solving the problems.

In order to achieve the purpose, the invention adopts the following technical scheme: a mold for manufacturing a precast concrete laminated slab for constructional engineering comprises a mold supporting frame, wherein the mold supporting frame comprises two supporting transverse plates which are arranged in parallel, and the front ends of the two supporting transverse plates are connected with a fixed mounting frame;

the mould shell is fixed on the two supporting transverse plates, inserting grooves are formed in the front end face and the rear end face of the mould shell at equal intervals from left to right, a control adjusting mechanism is arranged on the lower end face of the mould shell, auxiliary clamping mechanisms matched with the inserting grooves are symmetrically arranged at the front end and the rear end of the control adjusting mechanism, and vibration executing mechanisms are symmetrically arranged at the left end and the right end of the mould shell;

the driving operation mechanism is arranged on the fixed mounting frame and is used for controlling the vibration execution mechanism to work;

the mould shell is provided with a rectangular groove, the rectangular groove and the slot penetrating groove are integrally formed, and the width of the rectangular groove is larger than that of the slot penetrating groove.

The control adjusting mechanism comprises a double-shaft motor, the double-shaft motor is mounted on the lower end face of the die shell through a motor base, output shafts at two ends of the double-shaft motor are connected with one end of a lead screw through a coupler, the other end of the lead screw is fixed on a baffle through a bearing, the baffle is fixed on the lower end face of the die shell, moving grooves are formed in the lower end face of the die shell at equal intervals from left to right, supporting adjusting frames are arranged in the moving grooves in a sliding mode, the supporting adjusting frames are connected through T-shaped frames, threaded holes matched with the lead screw are formed in the T-shaped frames, and one ends, far away from the T-shaped frames, of the supporting adjusting frames are connected through connecting transverse plates;

supplementary chucking mechanism includes that turn right equidistant setting from a left side is in connect the supplementary execution piece on the diaphragm, the middle part of supplementary execution piece is provided with the through hole, the annular cavity has been seted up on the supplementary execution piece, the annular cavity with the inflation groove has evenly been seted up between the through hole, inflation groove department is provided with inflatable rubber pad, the last inflation cavity of having seted up of supplementary execution piece, inflation cavity with link to each other through the air vent between the annular cavity, set up on the supplementary execution piece and aerify the piston hole of cavity intercommunication, slide in the piston hole and be provided with the piston rod, the cover is equipped with reset spring between the outer wall of piston rod and supplementary execution piece, the piston rod is located the one end of inflation cavity is provided with the piston board, the parcel has the sealing rubber cover on the piston board.

The vibration executing mechanism comprises auxiliary plates arranged at the left end and the right end of the die shell, auxiliary holes are formed in the auxiliary plates at equal intervals from front to back, auxiliary executing rods are movably arranged in the auxiliary holes, the lower ends of the auxiliary executing rods are connected through the auxiliary executing plates, the auxiliary executing plates are connected with the auxiliary plates through auxiliary spring rods, auxiliary executing frames are arranged at the upper ends of the auxiliary executing rods and are in sliding connection with the inner wall of the die shell, driven rods are arranged at the lower ends of the auxiliary executing plates and abut against the driving operating mechanism.

The drive operation mechanism includes two-way motor, two-way motor passes through the motor cabinet to be installed on fixed mounting bracket, and the output shaft at two-way motor both ends all links to each other with the rotary rod through the shaft coupling, and the rotary rod runs through the bearing fixed mounting bracket, just the rotary rod is kept away from one of two-way motor serves and is provided with the worm, and the meshing has the worm wheel on the worm, and the worm wheel is fixed on the dwang, the dwang passes through the riser to be fixed on supporting the diaphragm, just be provided with the eccentric wheel on the dwang, the eccentric wheel supports and leans on the driven lever.

Hidden grooves are symmetrically formed in the front end and the rear end of the inner wall of the mold shell, mold bottom plates are arranged in the hidden grooves in a sliding mode, sliding holes communicated with the hidden grooves are symmetrically formed in the left end and the right end of the mold shell, sliding rods are arranged in the sliding holes, the sliding rods are connected with the mold bottom plates, sliding spring rods are arranged between the mold bottom plates and the inner walls of the hidden grooves, an auxiliary fixing frame is arranged at the front end of the auxiliary execution frame, an auxiliary guide frame is arranged on the auxiliary fixing frame, T-shaped grooves are formed in the auxiliary guide frame, and T-shaped blocks matched with the T-shaped grooves are arranged on the sliding rods.

In addition, the invention also provides a use method of the mold for manufacturing the constructional engineering concrete prefabricated laminated slab, which comprises the following steps of;

step one, binding steel bars into a shape required by manufacturing a laminated slab according to requirements, and checking the binding and fixing effect of binding and connecting parts of the steel bars;

placing the tied steel bars in the step one into a mould shell, and adjusting the positions of the steel bars in the mould shell;

starting the control adjusting mechanism to drive the auxiliary clamping mechanism to move to a position matched with the inserting groove, so that the mold shell forms a complete mold state, and raw materials for pouring the laminated plate are ensured not to overflow after being injected into the mold shell;

pouring the raw materials for manufacturing the laminated plate into a mold shell, and placing the mold shell at a ventilation position for airing so that the raw materials in the mold shell are solidified into a laminated plate structure;

and step five, starting the driving operation mechanism after the laminated slab in the mold shell is molded, and driving the vibration execution mechanism to move through the driving operation mechanism, so that the molded laminated slab is separated from the contact position of the mold shell, and the prefabricated molded laminated slab is convenient to take out from the mold shell.

Advantageous effects

1. The invention solves the following problems existing in the manufacturing process of the existing constructional engineering concrete prefabricated composite floor slab, the steel bars of the formed composite slab extend to the outer side of a concrete structure, the templates for pouring concrete need to be spliced manually when the concrete is poured, the positions of the steel bars extending out of the templates need to be blocked, the quantity of the steel bars extending out of the composite slab is large, the operation of blocking the steel bars extending out of the templates one by one is complex, the consumed time is long, the spliced templates need to be dismantled one by one when the templates are demolded in the formed composite slab, the damage to the surface of the composite slab is uniformly caused when the templates are dismantled manually, and the damaged composite slab after demolding needs to be repaired.

2. According to the invention, the reinforcing steel bars are bundled into a required structure, then the reinforcing steel bars are placed in the die shell, the position of the reinforcing steel bars is adjusted, the control adjusting mechanism is started to drive the auxiliary clamping mechanism to move to the position matched with the inserting groove, the reinforcing steel bars penetrate through the through holes, the auxiliary clamping mechanism enables the inflatable rubber pads to expand when moving to the specified position, the expanded inflatable rubber pads are tightly wrapped on the outer sides of the reinforcing steel bars, the raw materials injected into the die shell are ensured not to overflow, the position of the reinforcing steel bars extending out of the die plate is not required to be manually blocked, the operation is simple and convenient, and the operation is convenient

3. According to the invention, after the prefabricated laminated slab in the mold shell is molded, the auxiliary execution frame is controlled by the driving operation mechanism to move up and down, and the auxiliary execution frame is matched with the sliding rod to synchronously drive the mold bottom plate to move in the movement process, so that the molded laminated slab is separated from the mold bottom plate, the molded laminated slab is convenient to take out of the mold shell, and the laminated slab cannot be damaged.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a cross-sectional view of FIG. 1 of the present invention;

FIG. 3 is a cross-sectional view taken along line A-A of FIG. 2 in accordance with the present invention;

fig. 4 is a sectional view of the auxiliary clamping mechanism of the present invention.

Detailed Description

The embodiments of the invention will be described in detail below with reference to the drawings, but the invention can be implemented in many different ways as defined and covered by the claims.

As shown in fig. 1 to 4, a mold for manufacturing a precast concrete composite slab for construction engineering comprises a mold support frame 1, wherein the mold support frame 1 comprises two support transverse plates 11 which are arranged in parallel, and the front ends of the two support transverse plates 11 are connected with a fixed mounting frame 12;

the mold comprises a mold shell 2, the mold shell 2 is fixed on two supporting transverse plates 11, inserting grooves are formed in the front end surface and the rear end surface of the mold shell 2 at equal intervals from left to right, a control adjusting mechanism 21 is arranged on the lower end surface of the mold shell 2, auxiliary clamping mechanisms 22 matched with the inserting grooves are symmetrically arranged at the front end and the rear end of the control adjusting mechanism 21, and vibration executing mechanisms 23 are symmetrically arranged at the left end and the right end of the mold shell 2;

the driving operation mechanism 3 is arranged on the fixed mounting frame 12, and the driving operation mechanism 3 is used for controlling the vibration executing mechanism 23 to work;

the mould shell 2 is provided with a rectangular groove, the rectangular groove and the slot penetrating groove are integrally formed, and the width of the rectangular groove is larger than that of the slot penetrating groove.

Tie up into the structure that needs with the reinforcing bar, then place the reinforcing bar in the mould casing 2, adjust the position of reinforcing bar, make naked reinforcing bar pass and wear the slot, start-up control adjustment mechanism 21 drives supplementary chucking mechanism 22 and moves to and alternates slot complex position department, the raw materials pouring that will be used for making the superimposed sheet is to the mould casing 2 in, start drive operation mechanism 3 after the superimposed sheet shaping in the mould casing 2, drive vibration actuating mechanism 23 motion through drive operation mechanism 3, thereby make the position separation of fashioned superimposed sheet and the contact of mould casing 2, the preformed sheet of being convenient for takes out in the mould casing.

The control adjusting mechanism 21 comprises a double-shaft motor 211, the double-shaft motor 211 is mounted on the lower end face of the die shell 2 through a motor base, output shafts at two ends of the double-shaft motor 211 are connected with one end of a lead screw 212 through a coupler, the other end of the lead screw 212 is fixed on a baffle 213 through a bearing, the baffle 213 is fixed on the lower end face of the die shell 2, moving grooves are formed in the lower end face of the die shell 2 at equal intervals from left to right, supporting adjusting frames 214 are arranged in the moving grooves in a sliding mode, the supporting adjusting frames 214 are connected through a T-shaped frame 215, threaded holes matched with the lead screw 212 are formed in the T-shaped frame 215, and one end, far away from the T-shaped frame 215, of the supporting adjusting frame 214 is connected through a connecting transverse plate 216;

after the reinforcing steel bars are placed, the double-shaft motor 211 is started, the double-shaft motor 211 drives the lead screw 212 to rotate, the lead screw 212 drives the T-shaped frame 215 to move in a rotating process in a thread transmission mode, the T-shaped frame 215 drives the supporting adjusting frame 214 to adjust synchronously in the moving process, so that the auxiliary execution block 221 is controlled to be inserted into the insertion groove, when the auxiliary execution block 221 moves to a proper position, the auxiliary execution block 221 and the inner wall of the mold shell 2 are in the same plane, the end face of the mold shell 2 is in a flat state, and the end face of the formed laminated slab is guaranteed to be flat.

The auxiliary clamping mechanism 22 comprises auxiliary actuating blocks 221 which are arranged on the connecting transverse plate 216 at equal intervals from left to right, the middle part of the auxiliary execution block 221 is provided with a through hole, the auxiliary execution block 221 is provided with an annular cavity 222, an inflation groove is uniformly arranged between the annular cavity 222 and the through hole, an inflation rubber pad 223 is arranged at the inflation groove, the auxiliary execution block 221 is provided with an inflation cavity 224, the inflation cavity 224 is connected with the annular cavity 222 through a vent hole, the auxiliary execution block 221 is provided with a piston hole communicated with the inflation cavity 224, a piston rod 225 is arranged in the piston hole in a sliding mode, a return spring 226 is sleeved between the piston rod 225 and the outer wall of the auxiliary execution block 221, the piston rod 225 is located at one end of the inflation cavity 224 and is provided with a piston plate 227, and a sealing rubber sleeve wraps the piston plate 227.

When the connecting transverse plate 216 drives the auxiliary execution block 221 to move towards the mold housing 2, the placed steel bars pass through the through holes, in the process, the piston rod 225 on the auxiliary execution block 221 moves in a manner of being matched with the outer wall of the rectangular groove and moves towards the inside of the inflating cavity 224, the piston rod 225 drives the piston plate 227 to press air in the inflating cavity 224 into the annular cavity 222 in the moving process, the air flushed into the annular cavity 222 is extruded to the inflating rubber pad 223 from the inside of the inflating groove, so that the inflating rubber pad 223 expands, and the inflated rubber pad 223 after expansion is tightly wrapped on the outer side of the steel bars, so that raw materials injected into the mold housing 2 cannot overflow.

The vibration executing mechanism 23 includes auxiliary plates 231 disposed at the left and right ends of the mold housing 2, the auxiliary plates 231 are provided with auxiliary holes at equal intervals from front to back, auxiliary executing rods 232 are movably disposed in the auxiliary holes, the lower ends of the auxiliary executing rods 232 are connected through auxiliary executing plates 233, the auxiliary executing plates 233 are connected with the auxiliary plates 231 through auxiliary spring rods 234, the upper ends of the auxiliary executing rods 232 are provided with auxiliary executing frames 235, the auxiliary executing frames 235 are slidably connected with the inner wall of the mold housing 2, the lower ends of the auxiliary executing plates 233 are provided with driven rods 236, and the driven rods 236 abut against the driving operating mechanism 3.

Drive operation mechanism 3 includes two-way motor 31, two-way motor 31 passes through the motor cabinet to be installed on fixed mounting bracket 12, and the output shaft at two-way motor 31 both ends all links to each other with rotary rod 32 through the shaft coupling, and rotary rod 32 runs through the bearing fixed mounting bracket 12, just rotary rod 32 keeps away from one of two-way motor 31 is served and is provided with worm 33, and the meshing has worm wheel 34 on the worm 33, and worm wheel 34 is fixed on dwang 35, dwang 35 passes through riser 36 to be fixed on supporting diaphragm 11, just be provided with eccentric wheel 37 on the dwang 35, eccentric wheel 37 supports and leans on driven lever 236.

Hidden grooves are symmetrically formed in the front end and the rear end of the inner wall of the mold shell 2, mold bottom plates 24 are arranged in the hidden grooves in a sliding mode, sliding holes communicated with the hidden grooves are symmetrically formed in the left end and the right end of the mold shell 2, sliding rods 25 are arranged in the sliding holes, the sliding rods 25 are connected with the mold bottom plates 24, sliding spring rods are arranged between the mold bottom plates 24 and the inner walls of the hidden grooves, an auxiliary fixing frame 26 is arranged at the front end of the auxiliary execution frame 235, an auxiliary guide frame 27 is arranged on the auxiliary fixing frame 26, T-shaped grooves are formed in the auxiliary guide frame 27, and T-shaped blocks 28 matched with the T-shaped grooves are arranged on the sliding rods 25.

After the prefabricated composite slab in the mold shell 2 is molded, the bidirectional motor 31 is started, the bidirectional motor 31 controls the rotating rod 32 to rotate in the movement, the rotating rod 32 drives the worm 33 to rotate synchronously in the rotation process, the worm 33 cooperates with the worm wheel 34 to control the rotating rod 35 to rotate in the rotation process, the rotating rod 35 controls the eccentric wheel 37 to rotate in the rotation process, the eccentric wheel 37 cooperates with the driven rod 236 to control the auxiliary actuating rack 235 to move up and down in the rotation process, the auxiliary actuating rack 235 is separated from the end surface of the molded composite slab in the up and down movement process, the auxiliary actuating rack 235 synchronously drives the auxiliary guide rack 27 to move up and down through the auxiliary fixing rack 26 in the up and down movement process, the auxiliary guide rack 27 controls the sliding rod 26 to move back and forth in the up and down movement process, and the sliding rod 26 drives the mold bottom plate 24 to move synchronously in the movement process, thereby separating the molded composite slab from the mold bottom plate 24 and facilitating the removal of the molded composite slab from the mold housing 2.

step two, placing the tied steel bars in the step one in a mould shell 2, and adjusting the positions of the steel bars in the mould shell;

thirdly, starting the control and adjustment mechanism 21 to drive the auxiliary clamping mechanism 22 to move to a position matched with the penetration groove, so that the mold shell 2 forms a complete mold state, and raw materials for pouring the laminated slab are ensured not to overflow after being injected into the mold shell 2;

pouring the raw materials for manufacturing the laminated plate into the mold shell 2, and placing the mold shell 2 at a ventilation position for airing so that the raw materials in the mold shell 2 are solidified into a laminated plate structure;

and step five, starting the driving operation mechanism 3 after the laminated slab in the mold shell 2 is molded, and driving the vibration executing mechanism 23 to move through the driving operation mechanism 3, so that the molded laminated slab is separated from the position of the mold shell 2 in contact, and the prefabricated laminated slab can be conveniently taken out from the mold shell.

The present invention has been described in terms of the preferred embodiment, and it is not intended to be limited to the embodiment. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims

1. A mold for manufacturing a precast concrete composite slab for constructional engineering is characterized by comprising

The mould supporting frame (1), the mould supporting frame (1) comprises two supporting transverse plates (11) which are arranged in parallel, and the front ends of the two supporting transverse plates (11) are connected with a fixed mounting frame (12);

the mould comprises a mould shell (2), wherein the mould shell (2) is fixed on two supporting transverse plates (11), inserting grooves are formed in the front end surface and the rear end surface of the mould shell (2) at equal intervals from left to right, a control adjusting mechanism (21) is arranged on the lower end surface of the mould shell (2), auxiliary clamping mechanisms (22) matched with the inserting grooves are symmetrically arranged at the front end and the rear end of the control adjusting mechanism (21), and vibration executing mechanisms (23) are symmetrically arranged at the left end and the right end of the mould shell (2);

the driving operation mechanism (3), the driving operation mechanism (3) is arranged on the fixed mounting frame (12), and the driving operation mechanism (3) is used for controlling the vibration execution mechanism (23) to work;

the die shell (2) is provided with a rectangular groove, the rectangular groove and the slot penetrating groove are integrally formed, and the width of the rectangular groove is larger than that of the slot penetrating groove.

2. The mold for manufacturing the precast concrete laminated slab as claimed in claim 1, wherein the control and adjustment mechanism (21) comprises a double-shaft motor (211), the double-shaft motor (211) is mounted on the lower end surface of the mold housing (2) through a motor base, output shafts at two ends of the double-shaft motor (211) are connected with one end of a lead screw (212) through a coupler, the other end of the lead screw (212) is fixed on a baffle plate (213) through a bearing, the baffle plate (213) is fixed on the lower end surface of the mold housing (2), moving grooves are formed in the lower end surface of the mold housing (2) at equal intervals from left to right, supporting and adjusting frames (214) are slidably arranged in the moving grooves, the supporting and adjusting frames (214) are connected through T-shaped frames (215), threaded holes matched with the lead screw (212) are formed in the T-shaped frames (215), one end of the support adjusting frame (214) far away from the T-shaped frame (215) is connected through a connecting transverse plate (216).

3. The precast concrete composite slab manufacturing mold according to claim 1, wherein the auxiliary clamping mechanism (22) comprises auxiliary execution blocks (221) which are arranged on the connecting transverse plate (216) at equal intervals from left to right, a through hole is formed in the middle of each auxiliary execution block (221), an annular cavity (222) is formed in each auxiliary execution block (221), an air inflation groove is uniformly formed between each annular cavity (222) and the through hole, an air inflation rubber pad (223) is arranged at each air inflation groove, an air inflation cavity (224) is formed in each auxiliary execution block (221), each air inflation cavity (224) is connected with each annular cavity (222) through an air vent, a piston hole communicated with each air inflation cavity (224) is formed in each auxiliary execution block (221), and a piston rod (225) is arranged in each piston hole in a sliding manner, a return spring (226) is sleeved between the outer wall of the piston rod (225) and the outer wall of the auxiliary execution block (221), the piston rod (225) is located at one end of the inflation cavity (224) and is provided with a piston plate (227), and a sealing rubber sleeve is wrapped on the piston plate (227).

4. The mold for making a precast concrete composite slab according to claim 1, the vibration executing mechanism (23) comprises auxiliary plates (231) arranged at the left end and the right end of the die shell (2), auxiliary holes are arranged on the auxiliary plate (231) at equal intervals from front to back, auxiliary executing rods (232) are movably arranged in the auxiliary holes, the lower ends of the auxiliary executing rods (232) are connected through an auxiliary executing plate (233), the auxiliary executing plate (233) is connected with the auxiliary plate (231) through an auxiliary spring rod (234), an auxiliary executing frame (235) is arranged at the upper end of each auxiliary executing rod (232), the auxiliary executing frame (235) is connected with the inner wall of the mould shell (2) in a sliding way, the lower end of the auxiliary actuating plate (233) is provided with a driven rod (236), and the driven rod (236) abuts against the driving operation mechanism (3).

5. The mold for manufacturing a precast concrete laminated slab according to claim 1, the driving operation mechanism (3) comprises a two-way motor (31), the two-way motor (31) is installed on the fixed installation frame (12) through a motor base, output shafts at two ends of the two-way motor (31) are connected with a rotating rod (32) through couplers, the rotating rod (32) penetrates through the fixed installation frame (12) through a bearing, and one end of the rotating rod (32) far away from the bidirectional motor (31) is provided with a worm (33), the worm (33) is engaged with a worm wheel (34), the worm wheel (34) is fixed on the rotating rod (35), the rotating rod (35) is fixed on the supporting transverse plate (11) through a vertical plate (36), and an eccentric wheel (37) is arranged on the rotating rod (35), and the eccentric wheel (37) abuts against the driven rod (236).

6. The mold for making a precast concrete composite slab according to claim 1, hidden grooves are symmetrically arranged at the front end and the rear end of the inner wall of the die shell (2), a die bottom plate (24) is arranged in the hidden grooves in a sliding manner, the left end and the right end of the mould shell (2) are symmetrically provided with sliding holes communicated with the hidden groove, a sliding rod (25) is arranged in the sliding hole, the sliding rod (25) is connected with the mould bottom plate (24), a sliding spring rod is arranged between the mould bottom plate (24) and the inner wall of the hidden groove, an auxiliary fixing frame (26) is arranged at the front end of the auxiliary executing frame (235), an auxiliary guiding frame (27) is arranged on the auxiliary fixing frame (26), the auxiliary guide frame (27) is provided with a T-shaped groove, and the sliding rod (25) is provided with a T-shaped block (28) matched with the T-shaped groove.