CN107012833B - Water channel cast-in-situ forming machine - Google Patents

Abstract

The invention provides a canal cast-in-place forming machine, and belongs to the field of hydraulic machinery. The canal cast-in-place forming machine comprises a power supply assembly, a material mixing bin, a feeding bin, a material returning assembly and a forming die. The material mixing bin is connected with the feeding bin; the feeding bin is connected with the forming die. The forming die comprises a first discharging side edge and a second discharging side edge, and the first discharging side edge and the second discharging side edge are respectively positioned at two sides of the forming die; the feed back subassembly includes feed back section of thick bamboo and feed back propulsion subassembly, and the feed back passageway is enclosed into to the feed back section of thick bamboo, and the feed back section of thick bamboo includes first end and second end, and first ejection of compact side and/or second ejection of compact side are located to first end, and second end and material mix storehouse or feeding storehouse intercommunication, feed back propulsion subassembly are located in the feed back section of thick bamboo. The water channel cast-in-place forming machine provided by the invention can automatically recover and reuse materials leaked from two sides of the forming die, so that the material utilization rate is increased, and the labor cost in the water channel building process is reduced.

Description

Water channel cast-in-situ forming machine

Technical Field

The invention relates to the field of hydraulic machinery, in particular to a canal cast-in-place forming machine.

Background

A water channel cast-in-situ forming machine is a device which can pour cement into a water channel construction project and can form the water channel.

The existing canal cast-in-place forming machine has higher efficiency, but in the working process, a large amount of materials leak from the side edge of the forming die, and the leaked materials need to be shoveled back to the canal cast-in-place forming machine manually, so that the labor cost of the canal cast-in-place forming machine is increased.

Disclosure of Invention

The invention provides a water channel cast-in-place forming machine, and aims to solve the problems of the water channel cast-in-place forming machine in the prior art.

The invention is realized by the following steps:

a canal cast-in-place forming machine comprises a power supply assembly, a material mixing bin, a feeding bin, a material returning assembly and a forming die;

a material mixing component and a material mixing driving component are arranged in the material mixing bin, and the material mixing driving component is connected with a power supply component and the material mixing component;

the material mixing bin is connected with the feeding bin;

a feeder and a feeding driving part are arranged in the feeding bin, and the feeding driving part is connected with the power supply assembly and the feeder;

the feeding bin is connected with the forming die;

the forming die comprises a first discharging side edge and a second discharging side edge, and the first discharging side edge and the second discharging side edge are respectively positioned at two sides of the forming die;

the feed back subassembly includes feed back section of thick bamboo and feed back propulsion subassembly, and the feed back passageway is enclosed into to the feed back section of thick bamboo, and the feed back section of thick bamboo includes first end and second end, and first ejection of compact side and/or second ejection of compact side are located to first end, and second end and material mix storehouse or feeding storehouse intercommunication, feed back propulsion subassembly are located in the feed back section of thick bamboo.

In a preferred embodiment of the invention, the feed back cylinder comprises a cylinder base body and a material collecting plate, the material collecting plate is fixedly connected to a first end of the cylinder base body, the material collecting plate and the first end are arranged in parallel at intervals, and the material collecting plate is connected with the first end through a connecting piece.

In a preferred embodiment of the invention, the aggregate plate is provided with a first baffle plate and a second baffle plate, the first baffle plate and the second baffle plate are oppositely arranged, and the first baffle plate and the second baffle plate are respectively connected with the connecting piece.

In a preferred embodiment of the present invention, the feed back advancing assembly includes a feed back advancing rotating shaft extending along the length direction of the feed back cylinder, a feed back advancing plate which is a spiral plate, and a feed back driving member which is fixedly connected to the feed back advancing rotating shaft and is annularly arranged around the feed back advancing rotating shaft.

In a preferred embodiment of the present invention, the feed back cylinder comprises a first cylinder section, a second cylinder section and a third cylinder section which are vertically connected in sequence, and the first end is located at one end of the first cylinder section far away from the second cylinder section.

In a preferred embodiment of the present invention, the feedback drive assembly includes a vacuum generator connected to the second end.

In a preferred embodiment of the invention, the feeding bin is detachably connected with the forming die, the material returning cylinder is provided with a material returning connecting part, and the material returning connecting part is detachably connected with the feeding bin.

A canal cast-in-place forming machine comprises a power supply assembly, a material mixing bin, a feeding bin, a material returning assembly and a forming die;

a material mixing component and a material mixing driving component are arranged in the material mixing bin, and the material mixing driving component is connected with a power supply component and the material mixing component;

the material mixing bin is connected with the feeding bin;

a feeder and a feeding driving part are arranged in the feeding bin, and the feeding driving part is connected with the power supply assembly and the feeder;

the feeding bin is connected with the forming die;

the forming die comprises a first discharging side edge and a second discharging side edge, and the first discharging side edge and the second discharging side edge are respectively positioned at two sides of the forming die;

the feed back component comprises a feed back barrel and a feed back propelling component, the feed back barrel is enclosed into a feed back channel, the feed back barrel comprises a first end and a second end, the first end is arranged on the first discharging side edge and/or the second discharging side edge, the second end is communicated with the material mixing bin or the feeding bin, and the feed back propelling component is arranged in the feed back barrel;

the feeding bin is provided with an additive supplying piece, the feeder is provided with an additive containing cavity, the additive supplying piece is detachably connected with the additive containing cavity, and the additive containing cavity is communicated with the space in the feeding bin through an additive flow channel.

In a preferred embodiment of the invention, the feeder is of a cylindrical rod-shaped structure, one end of the feeder is connected with the feeding driving part, the outer surface of the feeder is provided with a spiral feeding blade, and one end of the feeder is connected with the feeding driving part;

the additive containing cavity is arranged in the center of the feeder, one end of the additive flow channel penetrates through the additive containing cavity, the other end of the additive flow channel penetrates into the feeding bin, and the axis of the additive flow channel extends along a plane spiral line.

In a preferred embodiment of the invention, the feeding bin is further provided with a connecting shaft, and the connecting shaft is connected with the feeding bin.

The invention has the beneficial effects that: according to the invention, when the water channel cast-in-place forming machine is used, the material returning component can collect materials leaked from two sides of the forming die and send the materials back to the feeding bin, so that the waste of the materials is reduced, the materials are not required to be shoveled back to the feeding bin by manpower, and the labor cost is saved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

Fig. 1 is a schematic structural view of a canal cast-in-place molding machine provided by an embodiment of the invention;

fig. 2 is a schematic internal structure view of a canal cast-in-place molding machine according to an embodiment of the invention;

FIG. 3 is an enlarged view of a portion III of FIG. 2;

FIG. 4 is a cross-sectional view of a feeder provided by an embodiment of the present invention;

FIG. 5 is a sectional view taken along the line A-A in FIG. 4;

FIG. 6 is a schematic view of a connection shaft provided by an embodiment of the present invention;

FIG. 7 is an enlarged view of a portion VII in FIG. 6;

FIG. 8 is a schematic structural view of a fastener provided in accordance with an embodiment of the present invention;

FIG. 9 is a schematic structural view of a moveable member provided in accordance with an embodiment of the present invention;

FIG. 10 is a schematic view of the internal structure of a feed back assembly provided by an embodiment of the invention;

fig. 11 is a schematic structural diagram of a material collecting plate according to an embodiment of the present invention.

Icon: 100-a water channel cast-in-place forming machine; 110-power supply components; 120-material mixing bin; 130-a feeding bin; 140-forming a mould; 112-a power supply; 114-a shock mount; 122-mixing parts; 123-stirring driving piece; 132-a first feeder; 134-a second feeder; 133-a first feed drive; 135-a second feed drive; 137-additive supply; 136-a connecting shaft; 1321-feeder blade; 1327-mounting vias; 1323-an additive-containing chamber; 1325-an additive flow channel; 138-a fastener; 139-a movable member; 1381-a snap-fit groove; 1391-a clamping block; 1382-pilot hole; 1383-a slider; 1392-bumps; 1394-groove; 1393-an elastic member; 150-a feed back assembly; 153-a feed back cylinder; 151-material collecting plate; 158-a vacuum generator; 159-a connecting portion; 152-a first barrel section; 155-a second barrel section; 157-a third barrel section; 1522-first feed back advancing spindle; 154-first pusher plate; 1526 first feed back connecting seat; 1512-a connector; 1514-a first baffle; 1516-second baffle; 142-a first discharge side; 144-second discharge side.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions of the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings of the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be obtained by a person skilled in the art without any inventive step based on the embodiments of the present invention, are within the scope of the present invention. Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. All other embodiments, which can be obtained by a person skilled in the art without any inventive step based on the embodiments of the present invention, are within the scope of the present invention.

In the description of the present invention, it is to be understood that the terms indicating an orientation or positional relationship are based on the orientation or positional relationship shown in the drawings only for the convenience of describing the present invention and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can, for example, be fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In the present invention, unless otherwise expressly stated or limited, the first feature may be present on or under the second feature in direct contact with the first and second feature, or may be present in the first and second feature not in direct contact but in contact with another feature between them. Also, the first feature being above, on or above the second feature includes the first feature being directly above and obliquely above the second feature, or merely means that the first feature is at a higher level than the second feature. A first feature that underlies, and underlies a second feature includes a first feature that is directly under and obliquely under a second feature, or simply means that the first feature is at a lesser level than the second feature.

Example (b):

referring to fig. 1 and 2, the cast-in-place canal molding machine 100 includes a power module 110, a material mixing bin 120, a feeding bin 130, a material returning module 150, and a molding die 140. The material mixing bin 120 is arranged at the upper part of the feeding bin 130 and is communicated with the feeding bin 130, and the feeding bin 130 is connected with the forming die 140.

The power supply assembly 110 includes a power supply 112 and a shock mount 114. The power source 112 is disposed on the shock mount 114 and is fixedly connected to the shock mount 114. The damper 114 is fixedly attached to the outer surface of the feed bin 130.

Further, the power source 112 is a diesel generator. The shock absorbing seat 114 is provided with a plurality of shock absorbing members. Specifically, the damping member is a spring.

The material mixing bin 120 is of a funnel-shaped structure, and the lower part of the material mixing bin 120 is communicated with the feeding bin 130. The material mixing bin 120 is provided with a material mixing part 122, and the material mixing part 122 is driven by a material mixing driving part 123. The stirring drive 123 is connected to the power source 112.

Further, the stirring member 122 is provided with a plurality of blades. Under the action of the stirring driving member 123, the stirring member 122 rotates, and the blades on the stirring member 122 stir the material.

The feeding bin 130 is provided therein with a first feeder 132, a second feeder 134, a first feeding drive 133 and a second feeding drive 135.

The first feeder 132 is driven by a first feed drive 133 and the second feeder 134 is driven by a second feed drive 135. The first feed drive 133 and the second feed drive 135 are both connected to the power source 112.

Referring to fig. 3, the housing of the feed bin 130 is connected to one end of an additive supply 137, and the other end of the additive supply 137 is connected to the first feeder 132.

Referring to fig. 4 and 5, in particular, the first feeder 132 has a cylindrical structure. The first feeder 132 is provided therein with an additive containing chamber 1323. The first feeder 132 is provided with a mounting through hole 1327. The mounting through-hole 1327 communicates the additive containing chamber 1323 and the inside of the feed bin 130. The additive supply member 137 is detachably coupled to the mounting through-hole 1327 to communicate the additive containing chamber 1323 with the space outside the canal cast-in-place molding machine 100. Thus, the operator can add the material additive into the additive containing chamber 1323 through the additive supplement 137.

Further, the first feeder 132 is provided with a plurality of additive flow passages 1325. One end of the additive flow passage 1325 is communicated with the additive accommodating chamber 1323, and the other end of the additive flow passage 1325 is communicated with the space in the feed bin 130. The axis of the additive flow passage 1325 is a planar spiral, and the axis of the additive flow passage 1325 extends across the cross-section of the first feeder 132 in which it is located.

Further, the first feeder 132 is provided at an outer surface thereof with a screw plate-shaped feeding blade 1321. As the first feeder 132 rotates, the feeding blade 1321 may push the material to the side of the molding die 140.

The second feeder 134 has the same structure as the first feeder 132.

Specifically, the additive replenishing member 137 may have two outlets, which are connected to the first feeder 132 and the second feeder 134, respectively; the same additive supply 137 may also be used to supply the additive to the inside of the first and second feeders 132 and 134, respectively.

When the first feeder 132 is driven by the first feeding driving member 133 and the second feeder 134 is driven by the second feeding driving member 135 to rotate, the spiral feeding blade 1321 can push the material in the feeding bin 130 to the forming die 140 side. The additive in the additive containing chamber 1323 is discharged from the additive containing chamber 1323 through the spiral additive flow passage 1325 as the first feeder 132 and the second feeder 134 rotate, so as to enter the feeding bin 130, and is uniformly mixed with the materials under the stirring of the first feeder 132 and the second feeder 134, so that different properties are provided to the materials.

Specifically, the material may be cement for canal formation, and the additive may be a quick-drying agent for changing the properties of ordinary cement.

Of course, the specific types of the materials and the additives can be selected according to actual construction requirements, so that diversified construction requirements are guaranteed.

Referring to fig. 6, the feeding bin 130 is further provided with a connecting shaft 136. The connecting shaft 136 is arranged on one side of the feeding bin 130 close to the forming die 140, and the direction of the connecting shaft 136 is perpendicular to the discharging direction of the feeding bin 130.

The connecting shaft 136 is composed of a fixed member 138 and a movable member 139. One end of a fixed member 138 is fixedly connected with the feeding bin 130, and the other end of the fixed member 138 is detachably connected with a movable member 139; one end of movable member 139 is removably connected to movable member 139 and the other end of movable member 139 is hingedly connected to feed bin 130.

The removable connection of fixed element 138 to mobile element 139 is realized in particular by:

referring to fig. 7, 8 and 9, a locking groove 1381 is formed on the fixing member 138, and a locking block 1391 adapted to the locking groove 1381 is formed on the movable member 139. The structure of the snap-in block 1391 is set as follows: the two planes parallel to the axial direction of the movable element 139 are used for cutting off the movable element 139, the obtained structure is the structure of the clamping block 1391, and the plane formed by the hinging and rotating track of the movable element 139 is parallel to the plane of the cut-off movable element 139.

The setting of above-mentioned structure for joint piece 1391 is at moving part 139 around the pivoted in-process of pin joint, can cooperate or the separation with joint groove 1381.

Furthermore, a guide hole 1382 is formed in the wall of the clamping groove 1381, and a sliding block 1383 is arranged in the guide hole 1382. The slider 1383 is slidably engaged with the guide hole 1382. The lateral wall of the clamping block 1391 is provided with a groove 1394 corresponding to the guide hole 1382, and the groove 1394 is connected with a bump 1392 through an elastic piece 1393. With the compression and recovery of the resilient member 1393, the protrusion 1392 can be fully retracted into the recess 1394 or partially extended into the guide hole 1382. The protrusion 1392 extending into the guide hole 1382 can be pressed back into the recess 1394 by the slider 1383.

When projection 1392 extends into guide aperture 1382, projection 1392 causes fixed member 138 and hinge 139 to snap together at the connection; if it is desired to disengage stationary member 138 from moveable member 139, the slider is depressed and a force is applied to moveable member 139.

During construction, the film roll may be sleeved over the connecting shaft 136. Before construction, one end of the film is fixed, the film roller rotates along with the advancing of the water channel cast-in-place forming machine 100, and the film is automatically covered on the constructed water channel, so that the construction requirement under special conditions is met.

If it is desired to replace the roll of film, the fixed member 138 and moveable member 139 are simply disengaged, the old roll of film removed and replaced with a new roll of film.

In the embodiment of the present invention, the feeding chamber 130 is detachably connected to the molding die 140. If the cross-sectional shape of the canal needs to be changed, the forming die 140 is removed and replaced.

The number of the material returning assemblies 150 is two, and the two material returning assemblies 150 are respectively arranged at two sides of the canal cast-in-place forming machine 100. The feed back assembly 150 includes a feed back barrel 153 and a feed back propulsion assembly.

Referring to fig. 10, the feed back cylinder 153 encloses a feed back channel. The reclaiming barrel 153 includes a barrel base and a material collecting plate 151. The cartridge base includes a first cartridge section 152, a second cartridge section 155, and a third cartridge section 157. The first cylinder section 152 and the third cylinder section 157 are arranged from top to bottom, and the second cylinder section 155 connects the first cylinder section 152 and the third cylinder section 157. The end of the first cylinder section 152 far away from the second cylinder section 155 is the first end of the feed back cylinder 153, and the end of the third cylinder section 157 far away from the second cylinder section 155 is the second end of the feed back cylinder 153.

The material collecting plates 151 are disposed opposite to the first end at intervals, and the material collecting plates 151 are connected to the first end through a connecting member 1512. Specifically, the connecting member 1512 is a plate-shaped structure.

Referring to fig. 11, the aggregate plate 151 is connected to a first baffle 1514 and a second baffle 1516. The first blocking plate 1514 and the second blocking plate 1516 are disposed opposite to each other, and both the first blocking plate 1514 and the second blocking plate 1516 are connected to the connecting member 1512. The first baffle 1514 and the second baffle 1516 are spaced apart a large distance at the ends thereof remote from the connecting members 1512 and a small distance at the ends thereof close to the connecting members 1512, so that the retainer plate 151 assumes an open structure.

The material return barrel 153 is provided with a material return pushing assembly, which includes a material return pushing shaft, a material return pushing plate and a material return driving member (not shown).

Specifically, a first material returning and pushing rotating shaft 1522 and a first material pushing and pushing plate 154 are arranged in the first barrel section 152, the material returning and driving member is connected with the first material returning and pushing rotating shaft 1522, and the first material returning and pushing rotating shaft 1522 is driven to rotate by the material returning and driving member. The first pushing and pushing plate 154 is a spiral plate, and the first pushing and pushing plate 154 is disposed around the first feeding back rotating shaft 1522 and connected to the first feeding back rotating shaft 1522. The driving energy of the feed back driving element comes from the power supply assembly 110.

The inner wall of the material return barrel 153 is provided with a first material return connecting seat 1526. The first feed back driving shaft 1522 is connected to the first feed back connecting seat 1526 through a bearing.

Further, a second feed back pushing rotating shaft and a second feed back pushing plate are correspondingly arranged in the second cylinder section 155. A third feed back pushing rotating shaft and a third feed back pushing plate are correspondingly arranged in the third cylinder section 157.

The connection manner of the second feed back pushing rotating shaft, the second feed back pushing plate, the third feed back pushing rotating shaft and the third feed back pushing plate in the second cylinder section 155 and the third cylinder section 157 is similar to that of each component in the first cylinder section 152, and is not described herein again.

A vacuum generator 158 is connected to the second end of the feed back cylinder 153.

The outer wall of the material return barrel 153 is also provided with a material return connecting part 159. The material return barrel 153 is detachably connected with the material mixing bin 120 through a material return connection 159.

The forming die 140 includes a first discharge side 142 and a second discharge side 144, and the first discharge side 142 and the second discharge side 144 are located on both sides of the forming die 140.

The first ends of the two feed back cylinders 153 are arranged at the first discharge side 142 and the second discharge side 144, respectively.

The water channel cast-in-place forming machine 100 provided by the embodiment of the invention has the beneficial effects that:

the return assemblies 150 are connected to both sides of the canal cast-in-place molding machine 100. During the traveling process of the canal cast-in-place molding machine 100, material is continuously extruded from the first discharging side 142 and the second discharging side 144 at the two ends of the molding die 140. The material extruded first is continuously accumulated under the thrust of the material extruded later, and enters the material recycling barrel 153. Under the dual action of the vacuum generator 158 and the material accumulation, the material in the material returning cylinder 153 flows along the material pushing assembly, enters the second cylinder section 155 from the first cylinder section 152, then enters the third cylinder section 157, and finally enters the material mixing bin 120 from the second end of the material returning cylinder 153 to be reused. By using the water channel cast-in-place forming machine 100 provided by the embodiment of the invention, the utilization efficiency of materials can be effectively improved, and the labor cost is reduced;

the material returning cylinder 153 is detachably connected with the material mixing bin 120, so that the proper material returning cylinder 153 can be replaced according to the shape of the forming die 140, and of course, in other embodiments of the invention, the material returning cylinder 153 can also be connected with the material feeding bin 130;

a spiral material pushing plate is arranged in the material returning barrel 153, materials in the material returning barrel 153 can be stacked along the material pushing plate, and collapse caused by excessive materials stacked in a vertical distance is avoided;

an additive containing cavity 1323 is arranged in a feeder of the canal cast-in-place forming machine 100, additives can be added into the additive containing cavity 1323 before construction, the additives are released into the feeding bin 130 along with the rotation of the feeder and are stirred by the feeder, so that the additives and materials are fully mixed, the materials can have various different performances, and different construction requirements are met;

the feed bin 130 of the water channel cast-in-place forming machine 100 is also provided with a connecting shaft 136, a film roller can be sleeved on the connecting shaft 136, and in the construction process, the film roller can rotate along with the movement of the water channel cast-in-place forming machine 100, so that a film is covered on the formed water channel, and the construction can be carried out in rainy days;

the forming die 140 of the canal cast-in-place forming machine 100 is detachably connected with the feeding bin 130, so that the forming die 140 can be replaced, and the construction requirements of canals with different section shapes are met.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. 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 (8)

1. A canal cast-in-place forming machine is characterized by comprising a power supply assembly, a material mixing bin, a feeding bin, a return assembly and a forming die;

a material mixing component and a material mixing driving component are arranged in the material mixing bin, and the material mixing driving component is connected with the power supply component and the material mixing component;

the material mixing bin is connected with the feeding bin;

a feeder and a feeding driving part are arranged in the feeding bin, and the feeding driving part is connected with the power supply assembly and the feeder;

the feeding bin is connected with the forming die;

the forming die comprises a first discharging side edge and a second discharging side edge, and the first discharging side edge and the second discharging side edge are respectively positioned at two sides of the forming die;

the feed back component comprises a feed back barrel and a feed back propelling component, the feed back barrel surrounds a feed back channel, the feed back barrel comprises a first end and a second end, the first end is arranged on the first discharging side edge and/or the second discharging side edge, the second end is communicated with the material mixing bin or the feeding bin, and the feed back propelling component is arranged in the feed back barrel;

the feed back cylinder comprises a cylinder base body and a material collecting plate, the material collecting plate is fixedly connected to a first end of the cylinder base body, the material collecting plate and the first end are arranged oppositely at intervals, and the material collecting plate is connected with the first end through a connecting piece.

2. The machine for cast-in-situ forming the ditch according to claim 1, wherein a first baffle plate and a second baffle plate are arranged on the material collecting plate, the first baffle plate and the second baffle plate are arranged oppositely, and the first baffle plate and the second baffle plate are respectively connected with the connecting piece.

3. The machine of claim 1, wherein the feed back propelling assembly comprises a feed back propelling rotating shaft, a feed back propelling plate and a feed back driving member, the feed back propelling rotating shaft extends along the length direction of the feed back barrel, the feed back propelling plate is a spiral plate, the feed back propelling plate is annularly arranged on the feed back propelling rotating shaft and is fixedly connected with the feed back propelling rotating shaft, and the feed back driving member is connected with the feed back propelling rotating shaft and the power supply assembly.

4. The cast-in-place canal molding machine of claim 3, wherein the material-returning barrel comprises a first barrel section, a second barrel section and a third barrel section which are vertically connected in sequence, and the first end is located at one end of the first barrel section, which is far away from the second barrel section.

5. The machine of claim 1, wherein the return assembly comprises a vacuum generator connected to the second end.

6. The machine of claim 1, wherein the feeding bin is detachably connected to the forming die, and the feed-back cylinder is provided with a feed-back connecting part which is detachably connected to the feeding bin.

7. A canal cast-in-place forming machine is characterized by comprising a power supply assembly, a material mixing bin, a feeding bin, a return assembly and a forming die;

a material mixing component and a material mixing driving component are arranged in the material mixing bin, and the material mixing driving component is connected with the power supply component and the material mixing component;

the material mixing bin is connected with the feeding bin;

a feeder and a feeding driving part are arranged in the feeding bin, and the feeding driving part is connected with the power supply assembly and the feeder;

the feeding bin is connected with the forming die;

the forming die comprises a first discharging side edge and a second discharging side edge, and the first discharging side edge and the second discharging side edge are respectively positioned at two sides of the forming die;

the feed back component comprises a feed back barrel and a feed back propelling component, the feed back barrel surrounds a feed back channel, the feed back barrel comprises a first end and a second end, the first end is arranged on the first discharging side edge and/or the second discharging side edge, the second end is communicated with the material mixing bin or the feeding bin, and the feed back propelling component is arranged in the feed back barrel;

the feeding bin is provided with an additive supplying piece, the feeder is provided with an additive containing cavity, the additive supplying piece is detachably connected with the additive containing cavity, and the additive containing cavity is communicated with the space in the feeding bin through an additive flow channel;

the feeder is of a cylindrical rod-shaped structure, one end of the feeder is connected with the feeding driving part, and spiral feeding blades are arranged on the outer surface of the feeder;

the additive containing cavity is arranged in the center of the feeder, one end of the additive flow channel penetrates through the additive containing cavity, the other end of the additive flow channel penetrates through the feeding bin, and the axis of the additive flow channel extends along a plane spiral line.

8. The cast-in-place canal molding machine as claimed in claim 7, wherein the feeding bin is further provided with a connecting shaft, and the connecting shaft is connected with the feeding bin.

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