CN116834140A - Automatic feeding device of tubular pile forming die - Google Patents

Abstract

The invention discloses an automatic feeding device of a tubular pile forming die, which relates to the technical field of tubular pile processing and comprises an automatic feeding mechanism, wherein an auxiliary mechanism is arranged on the automatic feeding mechanism, the auxiliary mechanism comprises an annular heat insulation block, an annular groove, a limiting ring, a positioning block, an auxiliary controller and a cylindrical hole, an electric heating ring is arranged in the annular groove near the bottom, wires are welded at the edges of the top of the electric heating ring near the two ends, a plurality of electric push rods are equidistantly distributed and arranged at the top of the annular block, a temperature sensor is arranged in the cylindrical hole, and a heat conducting sheet is fixed in each arc hole.

Description

Automatic feeding device of tubular pile forming die

Technical Field

The invention relates to the technical field of pipe pile processing, in particular to an automatic feeding device of a pipe pile forming die.

Background

The pipe pile is a foundation construction pile, mainly composed of concrete mortar and reinforcement cages, and is commonly used as a foundation support for structures such as buildings, bridges, wharfs and the like, and the concrete pipe pile is generally manufactured by using a pipe pile forming die, a concrete mortar feeding device and a centrifugal device in a matched manner.

In the actual use process of the automatic feeding device for the pipe pile forming die, although concrete mortar can be poured into the lower die of the pipe pile forming die rapidly, stably and uniformly, the automatic feeding device can not perform heating operation on the manufactured concrete mortar, when the pipe pile is required to be manufactured under the condition of lower environment, if the heating operation can not be performed on the concrete mortar, the setting time of the poured concrete mortar can be influenced, meanwhile, the water and the speed of the concrete mortar can be reduced, namely the strength of the manufactured pipe pile is influenced, and the use efficiency of the automatic feeding device is reduced.

Therefore, a new automatic feeding device for a pipe pile forming die needs to be proposed so as to solve the problems set forth in the above.

Disclosure of Invention

The invention aims to provide an automatic feeding device for a pipe pile forming die, which solves the problems that the existing automatic feeding device cannot perform heating operation on manufactured concrete mortar, and when pipe piles are manufactured under the condition of low environment, if the heating operation cannot be performed on the concrete mortar at the moment, the solidification time of the poured concrete mortar is influenced, and meanwhile, the water and the speed of the concrete mortar are reduced, namely the strength of the manufactured pipe piles is influenced, so that the service efficiency of the automatic feeding device is reduced.

In order to achieve the above purpose, the present invention provides the following technical solutions: the automatic feeding device of the tubular pile forming die comprises an automatic feeding mechanism, wherein an auxiliary mechanism is arranged on the automatic feeding mechanism;

the auxiliary mechanism comprises an annular heat insulation block, an annular groove, a limiting ring, a positioning block, an auxiliary controller and a cylindrical hole, wherein the heat insulation ring is arranged in the annular groove near the outlet, the electric heating ring is arranged in the annular groove near the bottom, wires are welded on the top of the electric heating ring near the edges of the two ends, a cover plate is arranged on the top of the annular heat insulation block, a sealing ring is bonded and connected to the bottom of the cover plate, a plurality of arc-shaped blocks are fixedly distributed on the outer surface of the cover plate at equal intervals, a plurality of electric push rods are fixedly distributed on the outer wall of the annular heat insulation block at equal intervals, two limiting rods are fixedly arranged on the lower side of each electric push rod, the auxiliary ring is movably sleeved on the outer surface of each electric push rod, a plurality of round rods are fixedly distributed on the bottom of the cover plate at equal intervals, the limiting rings are movably sleeved on the outer surface of each round rod, a temperature sensor is mounted in the inner wall of the cylindrical hole, a plurality of arc-shaped holes are fixedly provided with heat conducting sheets.

Preferably, the top of the electric heating ring contacts with the bottom of the heat insulation ring, one ends of the two wires are movably penetrated through the bottom of the heat insulation ring, the bottom of each limit rod is movably penetrated through the top of the circular ring block, the top of the telescopic end of each electric push rod is respectively installed with the bottom of each cambered surface block, one ends of the two wires are electrically connected with the auxiliary controller, and each electric push rod and each temperature sensor are electrically connected with the auxiliary controller.

Preferably, the automatic feeding mechanism comprises a placing table and a heat insulation plate, wherein the top of the placing table is fixedly provided with a treatment shell, the annular heat insulation block is fixedly sleeved on the outer wall of the treatment shell, the annular groove is formed in the top of the treatment shell, each limiting ring is fixedly sleeved on the inner wall of the treatment shell near the top, the positioning block is fixedly arranged on the outer wall of the treatment shell near the top, and the cylindrical hole is formed in the bottom of the inner wall of the treatment shell.

Preferably, the bottom of handling the shell is installed first motor, the bull stick is installed to the output of first motor, the top activity of bull stick runs through the bottom of handling the shell, the surface equidistance of bull stick distributes and is fixed with a plurality of puddlers, the mounting hole has been seted up to the inner wall bottom of handling the shell, the internally mounted of mounting hole has the motorised valve, one side of placing the platform is provided with the rack, one side that the rack is close to placing the platform is fixed with the connecting plate, the concrete pump is installed at the top of connecting plate, the inlet pipe is installed to the input of concrete pump, the input of inlet pipe is connected with the output of motorised valve.

Preferably, rectangular grooves are formed in the front surface and the rear surface of the placement frame, limiting grooves are formed in the bottoms of the inner walls of the rectangular grooves, rectangular holes are formed in the tops of the inner walls of the rectangular grooves, two symmetrical connecting blocks are fixed in the placement frame, a plurality of supporting blocks are distributed and fixed on the tops of the connecting blocks at equal intervals, the surfaces of the supporting blocks are fixed with the inner walls of the placement frame, two trapezoidal blocks are fixed on the front surface and the rear surface of the placement frame, and the four trapezoidal blocks are divided into two groups.

Preferably, one side of each group of the trapezoid blocks is movably penetrated with a single-head threaded rod, one end of each single-head threaded rod, which is close to the placing table, is respectively and rotatably connected to one side of each group of the other trapezoid blocks through a bearing, and one side of each group of one trapezoid block is provided with a second motor.

Preferably, the output end of each second motor is respectively installed with one end of each single-head threaded rod, each rectangular groove is internally provided with an auxiliary wheel, the lower side of each auxiliary wheel is respectively positioned in each limiting groove, and each hollow block is sleeved on the outer surface of each single-head threaded rod through threads.

Preferably, two opposite sides of the hollow block are respectively fixed with opposite sides of the two auxiliary wheels, a U-shaped frame is fixed between the tops of the two auxiliary wheels, the U-shaped frame is respectively and slidably connected between the interiors of the two rectangular holes, an infrared ranging sensor is mounted at the top of the U-shaped frame, and the detection end of the infrared ranging sensor movably penetrates through the top of the U-shaped frame.

Preferably, the top of the U-shaped frame is fixedly penetrated with a discharging guide pipe, the input end of the discharging guide pipe is provided with a discharging pipe, the input end of the discharging pipe is connected with the output end of the concrete pump, the heat insulation plate is fixed on the annular heat insulation block, the auxiliary controller is arranged on the front surface of the heat insulation plate, and the front surface of the heat insulation plate is provided with a main controller.

Preferably, the first motor, the electric valve, the concrete pump, the two second motors and the infrared ranging sensor are electrically connected with the main controller, an insulating block is arranged between two ends of the electric heating ring, an auxiliary frame is fixed on the surface of the U-shaped frame, and the discharging pipe is movably sleeved in the auxiliary frame.

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

1. according to the invention, by arranging the auxiliary mechanism, the well-stirred concrete mortar in the treatment shell can be heated, so that the solidification time of the concrete mortar and the strength of the tubular pile are ensured, the service efficiency of the automatic feeding device is improved, when the temperature of the well-stirred concrete mortar in the treatment shell needs to be controlled, the temperature of the concrete mortar can be intelligently controlled by utilizing the auxiliary controller, the temperature sensor, the heat conducting fin and the electric heating ring to be matched, then the cover plate can be moved up and down by utilizing the electric push rod, the circular ring block, the auxiliary ring and the cambered surface block to be matched, and then the cover plate and the sealing ring to be matched, so that the heated concrete mortar temperature can be prevented from losing.

2. According to the invention, by arranging the automatic feeding mechanism, the stirred concrete mortar can be automatically fed into the lower die on the pipe pile forming die, the working efficiency is high, when the automatic feeding operation of the pipe pile forming die is required, the material mixture for manufacturing the concrete mortar can be fully mixed by directly utilizing the cooperation of the main controller, the first motor, the rotating rod, the stirring rod and the processing shell, and then the horizontal movement of the U-shaped frame can be realized by utilizing the cooperation of the main controller, the second motor, the trapezoid block, the single-head threaded rod, the rectangular groove, the limiting groove, the rectangular hole, the auxiliary wheel and the hollow block, so that the horizontal movement of the discharging guide pipe is driven.

3. According to the invention, the mixed concrete mortar in the treatment shell can be pumped out and guided into the lower die on the tubular pile forming die by utilizing the matching of the main controller, the infrared ranging sensor, the concrete pump, the electric valve, the feeding pipe, the discharging pipe and the discharging guide pipe.

Drawings

FIG. 1 is a perspective view of an automatic feeding device for a tubular pile forming die according to the present invention;

FIG. 2 is a partial perspective view of an auxiliary mechanism of an automatic feeding device for a tubular pile forming die according to the present invention;

FIG. 3 is a partial perspective view of an auxiliary mechanism of an automatic feeding device for a tubular pile forming die in a top view;

FIG. 4 is a schematic perspective view of a processing shell, mounting holes, annular grooves and annular holes of an automatic feeding device for a tubular pile forming die;

FIG. 5 is a schematic perspective view of an insulating block, a heat insulating ring, an electric heating ring and a wire of an automatic feeding device for a pipe pile forming die;

FIG. 6 is a schematic perspective view of a seal ring, a cover plate and a round bar of an automatic feeding device for a pipe pile forming die;

FIG. 7 is a bottom perspective view of an automatic feeding device for a pipe pile forming die according to the present invention;

FIG. 8 is a schematic top view of a part of the automatic feeding device of a pipe pile forming die according to the present invention;

FIG. 9 is a partial perspective view of an automatic feeding mechanism of an automatic feeding device for a tubular pile forming die in a top view;

FIG. 10 is a schematic perspective view of an auxiliary wheel and hollow block of an automatic feeding device for a pipe pile forming die;

FIG. 11 is a schematic perspective view of an electric push rod and a stop lever of an automatic feeding device for a pipe pile forming die;

fig. 12 is a schematic view of a rear view angle part of an automatic feeding device for a pipe pile forming die according to the present invention.

In the figure: 1. an automatic feeding mechanism; 101. a placement table; 102. a treatment shell; 103. a first motor; 104. a rotating rod; 105. a stirring rod; 106. a mounting hole; 107. an electric valve; 108. a placing rack; 109. a connecting plate; 110. concrete pump; 111. a feed pipe; 112. rectangular grooves; 113. a limit groove; 114. a rectangular hole; 115. a connecting block; 116. a support block; 117. a trapezoid block; 118. a single-head threaded rod; 119. a second motor; 120. an auxiliary wheel; 121. a hollow block; 122. a U-shaped frame; 123. an infrared ranging sensor; 124. a discharge conduit; 125. a discharge pipe; 126. a heat insulating plate; 127. a main controller; 128. an insulating block; 129. an auxiliary frame; 2. an auxiliary mechanism; 201. an annular heat insulation block; 202. an annular groove; 203. a heat insulating ring; 204. an electric heating ring; 205. a wire; 206. a limiting ring; 207. a seal ring; 208. a cover plate; 209. a cambered surface block; 210. an electric push rod; 211. a limit rod; 212. a circular ring block; 213. an auxiliary ring; 214. a positioning block; 215. a round bar; 216. an auxiliary controller; 217. a cylindrical hole; 218. a temperature sensor; 219. an arc-shaped hole; 220. and a heat conductive sheet.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-12, the present invention provides a technical solution: the utility model provides an automatic feeding device of tubular pile forming die, including automatic feeding mechanism 1, be provided with auxiliary mechanism 2 on the automatic feeding mechanism 1, auxiliary mechanism 2 includes annular heat insulating block 201, annular groove 202, spacing ring 206, locating piece 214, auxiliary controller 216 and cylindrical hole 217, the inside of annular groove 202 is close to the exit position and is provided with heat insulating ring 203, the inside of annular groove 202 is close to the bottom position and is provided with electric heating ring 204, electric heating ring 204's top is close to both ends edge and all welds wire 205, annular heat insulating block 201's top is provided with apron 208, apron 208's bottom bonding is connected with sealing ring 207, apron 208's surface equidistance distributes and is fixed with a plurality of cambered surface pieces 209, annular heat insulating block 201's outer wall is fixed with ring piece 212, a plurality of electric putter 210 are installed to the top equidistance distribution of ring piece 212, the downside of every electric putter 210 all is fixed with two gag lever 211, the surface of every electric putter 210 has all movably sleeved auxiliary ring 213, apron 208's bottom equidistance distribution is fixed with a plurality of round bars 215, spacing ring 206 have all been movably sleeved on the surface of every round bar 215, the inside of cylindrical hole 217 installs temperature sensor 202, inside of annular groove 219 has a plurality of cambered surface 219, every cambered surface 219 is distributed and is provided with a plurality of cambered surface 219.

According to the embodiments shown in fig. 2, 3, 5, 8 and 11, the top of the electric heating ring 204 is contacted with the bottom of the heat insulation ring 203, one ends of the two wires 205 are movably penetrated through the bottom of the heat insulation ring 203, the bottom end of each limit rod 211 is movably penetrated through the top of the circular ring block 212, the top of the telescopic end of each electric push rod 210 is respectively installed with the bottom of each cambered surface block 209, one end of each wire 205 is electrically connected with the auxiliary controller 216, each electric push rod 210 and each temperature sensor 218 are electrically connected with the auxiliary controller 216, and the opening and closing operation of the electric heating ring 204 can be intelligently controlled under the cooperation of the auxiliary controller 216 and the temperature sensor 218.

According to the figures 1-4, 7 and 8, the automatic feeding mechanism 1 comprises a placing table 101 and a heat insulation plate 126, a processing shell 102 is fixed at the top of the placing table 101, an annular heat insulation block 201 is fixedly sleeved on the outer wall of the processing shell 102, an annular groove 202 is formed at the top of the processing shell 102, each limiting ring 206 is fixedly sleeved on the inner wall of the processing shell 102 and is close to the top, a positioning block 214 is fixedly arranged on the outer wall of the processing shell 102 and is close to the top, a cylindrical hole 217 is formed at the bottom of the inner wall of the processing shell 102, and the material mixture poured into the processing shell 102 can be fully stirred and mixed under the cooperation of the processing shell 102, a first motor 103, a rotating rod 104 and a stirring rod 105 to prepare concrete mortar.

According to the embodiments shown in fig. 2-4, fig. 7-9 and fig. 12, the bottom of the processing shell 102 is provided with the first motor 103, the output end of the first motor 103 is provided with the rotating rod 104, the top end of the rotating rod 104 movably penetrates through the bottom of the processing shell 102, the outer surface of the rotating rod 104 is provided with a plurality of stirring rods 105 in an equidistant distribution manner, the bottom of the inner wall of the processing shell 102 is provided with a mounting hole 106, the interior of the mounting hole 106 is provided with an electric valve 107, one side of the placing table 101 is provided with a placing rack 108, one side of the placing rack 108, which is close to the placing table 101, is provided with a connecting plate 109, the top of the connecting plate 109 is provided with a concrete pump 110, the input end of the concrete pump 110 is provided with a feeding pipe 111, and the input end of the feeding pipe 111 is connected with the output end of the electric valve 107, so that whether the concrete mortar manufactured in the processing shell 102 can be released or not under the action of the electric valve 107 is controlled.

According to the embodiment shown in fig. 7-9 and 12, rectangular grooves 112 are formed in the front surface and the rear surface of the placement frame 108, limiting grooves 113 are formed in the bottom of the inner wall of each rectangular groove 112, rectangular holes 114 are formed in the top of the inner wall of each rectangular groove 112, two symmetrical connecting blocks 115 are fixed in the placement frame 108, a plurality of supporting blocks 116 are uniformly distributed and fixed on the top of each connecting block 115, the surface of each supporting block 116 is fixed with the inner wall of the placement frame 108, two trapezoid blocks 117 are fixed on the front surface and the rear surface of the placement frame 108, the four trapezoid blocks 117 are divided into two groups, and the second motor 119 can conveniently drive a single-head threaded rod 118 connected with the second motor 119 to stably rotate under the action of the trapezoid blocks 117.

According to the embodiments shown in fig. 2, 3, 7 and 12, one side of each of the trapezoid blocks 117 movably penetrates through a single-head threaded rod 118, one end of each single-head threaded rod 118, which is close to the placement table 101, is respectively and rotatably connected to one side of each of the other trapezoid blocks 117 through a bearing, and a second motor 119 is mounted on one side of each of the trapezoid blocks 117, so that power support can be provided for movement of the U-shaped frame 122 under the action of the second motor 119.

According to the embodiments shown in fig. 7, 10 and 12, the output end of each second motor 119 is respectively mounted with one end of each single-head threaded rod 118, the auxiliary wheel 120 is disposed in each rectangular groove 112, the lower side of each auxiliary wheel 120 is respectively disposed in each limit groove 113, the outer surface of each single-head threaded rod 118 is respectively in threaded connection with a hollow block 121, and the auxiliary wheel 120 can be driven to horizontally move under the cooperation of the hollow block 121, the single-head threaded rod 118, the trapezoidal block 117, the second motor 119, the rectangular groove 112 and the limit grooves 113.

According to the embodiments shown in fig. 7, 9, 10 and 12, the opposite sides of the two hollow blocks 121 are respectively fixed with the opposite sides of the two auxiliary wheels 120, a U-shaped frame 122 is fixed between the tops of the two auxiliary wheels 120, the U-shaped frame 122 is respectively slidably connected between the interiors of the two rectangular holes 114, the top of the U-shaped frame 122 is provided with an infrared ranging sensor 123, and the detection end of the infrared ranging sensor 123 movably penetrates through the top of the U-shaped frame 122, so that the concrete pump 110 and the electric valve 107 can be intelligently controlled to perform opening and closing operations under the cooperation of the infrared ranging sensor 123 and the main controller 127.

According to the embodiments shown in fig. 2, 3, 7 and 12, the top of the U-shaped frame 122 is fixedly penetrated with a discharge conduit 124, the input end of the discharge conduit 124 is provided with a discharge pipe 125, the input end of the discharge pipe 125 is connected with the output end of the concrete pump 110, the heat insulation plate 126 is fixed on the annular heat insulation block 201, the auxiliary controller 216 is installed on the front surface of the heat insulation plate 126, the front surface of the heat insulation plate 126 is provided with a main controller 127, and the opening and closing operations of the equipment electrically connected with the main controller 127 can be controlled under the action of the main controller 127.

According to the illustrations in fig. 2, 3, 5, 7 and 12, the first motor 103, the electric valve 107, the concrete pump 110, the two second motors 119 and the infrared ranging sensor 123 are all electrically connected with the main controller 127, an insulating block 128 is arranged between two ends of the electric heating ring 204, an auxiliary frame 129 is fixed on the surface of the U-shaped frame 122, the discharging pipe 125 is movably sleeved in the auxiliary frame 129, and the discharging pipe 125 can be prevented from influencing the feeding operation of the automatic feeding device under the action of the auxiliary frame 129.

The whole mechanism achieves the following effects: when concrete mortar needs to be injected into the pipe pile forming mold, firstly placing an automatic feeding device on the ground, then connecting a main controller 127 and an auxiliary controller 216 with an external power supply, then opening the main controller 127 and the auxiliary controller 216, setting a distance threshold and a temperature threshold, when all are ready, firstly placing a lower mold on the pipe pile forming mold between the outer surfaces of a plurality of support blocks 116, adjusting the positions, then respectively installing upper end plates at two ends of a steel reinforcement cage which is pricked, then placing the steel reinforcement cage which is provided with the end plates in the lower mold, adjusting the positions, then synchronously starting all electric push rods 210 by utilizing the auxiliary controller 216, at this moment, directly driving a cover plate 208 to move together under the cooperation of a circular ring block 212, a limit rod 211 and a corresponding auxiliary ring 213 and an arc surface block 209, when the cover plate 208 moves, and the cover plate 208 moves at this moment, driving a sealing ring 207 to move, respectively moving each circular rod 215 to move from the inside of each limit ring 206, when the cover plate 208 moves to the position, directly resetting the electric push rods 210 to the position of the electric push rods 103 when the cover plate 208 does not move to the electric controller 216, directly resetting all electric push rods 210 to the position, directly completing the initial position and directly starting of the electric push rods 104 by utilizing the electric push rods, directly after all the electric push rods 210 are directly being matched with the electric push rods 104, and directly starting all the electric rods 104, directly and directly starting the electric push rods 104 when the electric rods are directly and directly at the position of the electric rods 104, when all materials in the processing shell 102 are uniformly stirred, the auxiliary controller 216 does not shut down the first motor 103 when all materials in the processing shell 102 are uniformly stirred for a period of time, meanwhile, when the auxiliary controller 216 is opened, the temperature sensor 218 also monitors the temperature of the mixture stirred in the processing shell 102 at all times and transmits detected temperature data to the inside of the auxiliary controller 216 in an electric signal mode, when the auxiliary controller 216 receives the transmitted temperature data, the auxiliary controller 216 directly compares the received temperature data with a temperature threshold value set in advance by the auxiliary controller 216, when the temperature data received by the auxiliary controller 216 is lower than the temperature threshold value set in advance by the auxiliary controller 216, at the moment, the auxiliary controller 216 directly starts the electric heating ring 204 through the cooperation of the two wires 205, the heating end of the started electric heating ring 204 heats up and transfers the generated heat to each heat conducting fin 220 contacted with the heating end, then the heat conducting fin transfers the generated heat to the concrete mortar in the processing shell 102, the concrete mortar is heated, when the temperature data received by the auxiliary controller 216 reaches the temperature threshold value set in advance by the auxiliary controller 216, the auxiliary controller 216 directly closes the electric heating ring 204, at the moment, the main controller 127 is utilized to synchronously start two second motors 119, at the moment, the two started second motors 119 directly drive the corresponding auxiliary wheels 120 to horizontally move under the cooperation of the corresponding group of trapezoidal blocks 117, the single-head threaded rod 118, the rectangular groove 112, the limiting groove 113 and the hollow block 121, the two moving auxiliary wheels 120 directly drive the U-shaped frame 122 to horizontally move together under the cooperation of the two rectangular holes 114, when the U-shaped frame 122 moves, the moving U-shaped frame 122 also drives the infrared ranging sensor 123, the discharging conduit 124 and the auxiliary frame 129 to move, meanwhile, after the main controller 127 is opened, the infrared ranging sensor 123 also monitors the reflected light (i.e. the distance between the infrared ranging sensor 123 and the object reflecting the light) at all times, and transmits the detected distance data to the main controller 127 in an electrical signal manner, when the main controller 127 receives the transmitted distance data, the main controller 127 directly compares the received distance data with the distance threshold set in advance by the main controller 127, when the distance data received by the main controller 127 is different from the distance threshold set in advance by the main controller 127, the main controller 127 will not start the electric valve 107 and the concrete pump 110 at this time, when the distance data received by the main controller 127 is the same as the distance threshold set in advance by the main controller 127, the main controller 127 directly starts the concrete pump 110 and the electric valve 107, the concrete mortar in the processing shell 102 is pumped by the concrete pump 110 started at this time under the cooperation of the electric valve 107, the feeding pipe 111 and the discharging pipe 125, guided to the inside of the discharging pipe 124, then output from the output end of the discharging pipe 124, and conveyed to the lower die of the pipe pile forming die, when the distance data received again by the main controller 127 is the same as the distance threshold set in advance by the main controller 127, the main controller 127 closes the concrete pump 110 and the electric valve 107, the concrete mortar in the processing shell 102, the feeding pipe 111, the inside of the discharging pipe 124 and the inside of the discharging pipe 125 is pumped completely, then the main controller 127 controls the two second motors 119 to perform inversion operation until the U-shaped frame 122 is reset to the initial position, after the U-shaped frame 122 is reset to the initial position, the main controller 127 directly and synchronously closes the two second motors 119, then allows the worker to butt-joint the upper die and the lower die on the pipe pile forming die together and fix the upper die and the lower die, then removes the pipe pile forming die from between the outer surfaces of the plurality of supporting blocks 116, then allows the worker to perform prestress tension operation, and then performs centrifugal operation by using a centrifugal device, thus obtaining the concrete pipe pile.

Wherein, the main controller 127 and the auxiliary controller 216 are both PLC controllers; the first motor 103, the electric valve 107, the concrete pump 110, the second motor 119, the infrared ranging sensor 123, the electric heating ring 204, the electric push rod 210, and the temperature sensor 218 are all prior art, and are not explained here too much.

Although the present invention has been described with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements and changes may be made without departing from the spirit and principles of the present invention.

Claims (10)

1. An automatic feeding device of tubular pile forming die, its characterized in that: the automatic feeding device comprises an automatic feeding mechanism (1), wherein an auxiliary mechanism (2) is arranged on the automatic feeding mechanism (1);

the auxiliary mechanism (2) comprises an annular heat insulation block (201), an annular groove (202), a limiting ring (206), a positioning block (214), an auxiliary controller (216) and a cylindrical hole (217), wherein the heat insulation ring (203) is arranged in the annular groove (202) close to an outlet, an electric heating ring (204) is arranged in the annular groove (202) close to the bottom, wires (205) are welded on the top of the electric heating ring (204) close to the edges of two ends, a cover plate (208) is arranged on the top of the annular heat insulation block (201), a sealing ring (207) is connected to the bottom of the cover plate (208) in an adhesive manner, a plurality of arc blocks (209) are fixedly distributed on the outer surface of the cover plate (208), a circular ring block (212) is fixedly arranged on the outer wall of the annular heat insulation block (201), a plurality of electric push rods (210) are uniformly distributed on the top of the circular ring block (212), two limiting rods (211) are fixedly arranged on the lower side of each electric push rod (210), an auxiliary ring (208) is movably sleeved on the outer surface of each electric push rod (210), a plurality of circular rods (215) are fixedly connected to the outer surface of the circular ring block (212), a plurality of circular ring blocks (215) are fixedly arranged on the outer surface of the circular ring block (212), a plurality of arc holes (219) are formed in the inner wall of the annular groove (202) in an equidistant distribution mode, and heat conducting fins (220) are fixed inside each arc hole (219).

2. The automatic feeding device for a pipe pile forming die according to claim 1, wherein: the top of electrical heating ring (204) contacts with the bottom of insulating ring (203), two the one end of wire (205) all runs through the bottom of insulating ring (203) actively, every the bottom of gag lever post (211) all runs through the top of ring piece (212) actively, every the flexible end top of electric putter (210) is installed with the bottom of every cambered surface piece (209) respectively, two the one end of wire (205) all with assist controller (216) electric connection, every electric putter (210), temperature sensor (218) all with assist controller (216) electric connection.

3. The automatic feeding device for a pipe pile forming die according to claim 1, wherein: automatic feed mechanism (1) is including placing platform (101) and heat insulating board (126), the top of placing platform (101) is fixed with handles shell (102), annular heat insulating block (201) is fixed to be cup jointed in the outer wall of handling shell (102), ring channel (202) are seted up in the top of handling shell (102), every spacing ring (206) are all fixed to be cup jointed in the inner wall of handling shell (102) and are close to top position, locating piece (214) are fixed in the outer wall of handling shell (102) and are close to top position, cylinder hole (217) are seted up in the inner wall bottom of handling shell (102).

4. An automatic feeding device for a tubular pile forming die according to claim 3, wherein: the utility model discloses a concrete pump (110) is installed to the bottom of handling shell (102), first motor (103) is installed to the bottom of handling shell (102), bull stick (104) is installed to the output of first motor (103), the top activity of bull stick (104) runs through the bottom of handling shell (102), the surface equidistance of bull stick (104) distributes and is fixed with a plurality of puddlers (105), mounting hole (106) have been seted up to the inner wall bottom of handling shell (102), mounting hole (106) internally mounted has motorised valve (107), one side of placing stage (101) is provided with rack (108), one side that rack (108) is close to placing stage (101) is fixed with connecting plate (109), concrete pump (110) are installed at the top of connecting plate (109), inlet pipe (111) are installed to the input of concrete pump (110), the input of inlet pipe (111) is connected with the output of motorised valve (107).

5. The automatic feeding device for a pipe pile forming die according to claim 4, wherein: rectangular grooves (112) are formed in the front surface and the rear surface of the placement frame (108), limiting grooves (113) are formed in the bottoms of the inner walls of the rectangular grooves (112), rectangular holes (114) are formed in the tops of the inner walls of the rectangular grooves (112), two symmetrical connecting blocks (115) are fixed in the placement frame (108), a plurality of supporting blocks (116) are distributed and fixed on the tops of the connecting blocks (115) at equal intervals, the surfaces of the supporting blocks (116) are fixed with the inner walls of the placement frame (108), two trapezoidal blocks (117) are fixed on the front surface and the rear surface of the placement frame (108), and the four trapezoidal blocks (117) are divided into two groups.

6. The automatic feeding device for a pipe pile forming die according to claim 5, wherein: one side of each group of trapezoidal blocks (117) is movably penetrated by a single-head threaded rod (118), one end of each single-head threaded rod (118) close to the placing table (101) is respectively and rotatably connected to one side of the other trapezoidal block (117) of each group through a bearing, and one side of each group of trapezoidal blocks (117) is provided with a second motor (119).

7. The automatic feeding device for a pipe pile forming die according to claim 6, wherein: the output end of each second motor (119) is respectively installed with one end of each single-head threaded rod (118), each rectangular groove (112) is internally provided with an auxiliary wheel (120), the lower side of each auxiliary wheel (120) is respectively located in each limit groove (113), and each hollow block (121) is sleeved on the outer surface of each single-head threaded rod (118) in a threaded mode.

8. The automatic feeding device for a pipe pile forming die according to claim 7, wherein: two opposite sides of hollow piece (121) are fixed with the opposite sides of two auxiliary wheel (120) respectively, two be fixed with U type frame (122) between the top of auxiliary wheel (120), U type frame (122) sliding connection respectively is between the inside of two rectangular holes (114), infrared ranging sensor (123) are installed at the top of U type frame (122), and the detection end activity of infrared ranging sensor (123) runs through the top of U type frame (122).

9. The automatic feeding device for a pipe pile forming die according to claim 8, wherein: the top of U type frame (122) is fixed to be run through has ejection of compact pipe (124), discharging pipe (125) are installed to the input of ejection of compact pipe (124), the input of discharging pipe (125) is connected with the output of concrete pump (110), heat insulating board (126) are fixed at annular heat insulating block (201), secondary control ware (216) are installed on the front surface of heat insulating board (126), main control ware (127) are installed on the front surface of heat insulating board (126).

10. The automatic feeding device for a pipe pile forming die according to claim 9, wherein: the novel energy-saving electric energy-saving control device is characterized in that the first motor (103), the electric valve (107), the concrete pump (110), the two second motors (119) and the infrared ranging sensor (123) are electrically connected with the main controller (127), an insulating block (128) is arranged between two ends of the electric heating ring (204), an auxiliary frame (129) is fixed on the surface of the U-shaped frame (122), and the discharging pipe (125) is movably sleeved in the auxiliary frame (129).