CN110733118A

CN110733118A - tower type mortar stirring device

Info

Publication number: CN110733118A
Application number: CN201910944987.5A
Authority: CN
Inventors: 邹涛
Original assignee: Changxin Ou Rootasia New Building Materials Co Ltd
Current assignee: Changxin Ou Rootasia New Building Materials Co Ltd
Priority date: 2019-09-30
Filing date: 2019-09-30
Publication date: 2020-01-31

Abstract

The invention provides tower type mortar stirring device, which comprises a stirring tower, a sand adding pipe, a liquid adding pipe, a support column, an upper filter screen plate, a manhole , a control box, a touch screen, a control host, a slurry guide hopper structure capable of being observed and filtered, a mortar stirring shaft structure, an anti-blocking vibration hammer structure, a material supplementing and mixing box structure, a power switch and a support base.

Description

tower type mortar stirring device

Technical Field

The invention belongs to the technical field of construction machinery, and particularly relates to an tower type mortar stirring device.

Background

In the projects with small mortar usage amount and long construction operation lines, such as municipal roads, public pipes (culverts), landscaping and the like, under the condition of strict dust pollution prevention, the state regulates the policy of stirring mortar in advance, and requires active use of dry-mixed ready-mixed mortar (wet-mixed mortar cannot be stored and is ready to be mixed), a dry-mixed ready-mixed mortar storage tank is required to be arranged for on-site use, the storage tank is mainly used for storing cement, fly ash, sand and other materials, during production, the cement, fly ash and sand are conveyed into a proportioning bin according to the requirements of customers to be stirred and discharged, the ready-to-use mortar mixing can be realized, the construction time is saved, the waste of mortar materials is reduced, the mortar can be prevented from being stacked on a construction site, the sanitation condition of construction is effectively improved, the environmental pollution is reduced, and the civilized construction.

In addition, the invention provides a portable cement processing towers with the Chinese patent publication No. CN108858792A, which comprises a frame body, a batch feeder, water and an additive system, wherein an operation room is arranged on the side of the frame body , a control system is arranged behind the operation room, a batching machine is arranged on the upper portion of the frame body, a sand and stone storage hopper is arranged on the side of the batching machine , a cement weighing hopper is arranged on the other side of the batching machine , a cement bin is arranged on the side of the frame body, close to of the cement weighing hopper, an air path system is arranged below the cement bin, the cement bin conveys cement into the cement weighing hopper through a cement screw machine, a mixer is arranged at the bottom of the batching machine, and a concrete storage hopper communicated with the mixer is arranged at the bottom of the mixer.

In view of the above, it is very necessary to invent tower type mortar stirring devices.

Disclosure of Invention

The invention provides a tower type mortar stirring device for solving the technical problems that an existing tower type mortar stirring device is poor in mortar mixing efficiency and easy to block a filter screen plate and inconvenient to view the mixing condition of mortar, tower type mortar stirring device comprises a stirring tower, a sand adding pipe, a liquid adding pipe, a supporting column, an upper filter screen plate, a manhole , a control box, a touch screen, a control host, a slurry guide hopper structure capable of filtering and observing, a mortar stirring shaft structure, an anti-blocking hammer structure, a material supplementing mixing box structure, a power switch and a supporting cushion seat, wherein the sand adding pipe is embedded in the middle position of the upper surface of the stirring tower, the liquid adding pipe is embedded in the upper position of the right side of the stirring tower, the end of the supporting column is respectively bolted at four corners of the lower surface of the stirring tower, the other end of the supporting column is bolted at the middle position of the upper surface of the supporting cushion seat, the upper filter screen plate is transversely bolted at the upper side position of the inner part of the stirring tower, the manhole is hinged to the right side of the buffer storage position of the stirring tower, the control box is connected with a connecting plate of the lower buffer storage box, the buffer storage box of the buffer storage box, the buffer storage box is connected with a screw of the buffer storage structure of the buffer storage box, the buffer storage plate of the buffer storage box is connected with the buffer storage box, the buffer storage box is connected with the buffer storage box, the buffer storage box is connected with the buffer storage box, the.

Preferably, the mortar stirring shaft structure comprises an L-shaped supporting plate, a stirring motor, a stirring shaft, a connecting sleeve, a locking bolt and a stirring rod, wherein the stirring motor is connected to the upper surface of the L-shaped supporting plate through the bolt; the stirring shaft coupler is connected to an output shaft of the stirring motor; the connecting sleeve is sleeved on the outer surface of the stirring shaft and is tightly propped and fixed by a locking bolt; the locking bolt is in threaded connection with the middle position of the outer surface of the connecting sleeve; the stirring rods are respectively bolted on the middle positions of the upper surface and the lower surface of the connecting sleeve.

Preferably, the anti-blocking vibration hammer structure comprises a vibration motor, a connecting rod, a supporting plate, an upper vibration hammer and a lower vibration hammer, wherein the end of the connecting rod is connected to an output shaft of the vibration motor through a screw, the other end is connected to the upper portion and the lower portion of the right side of the supporting plate through bolts respectively, and the upper vibration hammer and the lower vibration hammer are connected to the upper portion and the lower portion of the front surface of the supporting plate through bolts respectively.

Preferably, the material supplementing and mixing box structure comprises a mixing box, a material supplementing hopper, a material discharging pipe, an L-shaped supporting seat, a ball bearing, a feeding motor and a feeding auger, wherein the material supplementing hopper is connected to the left side of the upper surface of the mixing box through a bolt and communicated with the inside of the mixing box, the material discharging pipe is connected to the left side of the lower surface of the mixing box through a bolt and communicated with the inside of the mixing box, the feeding motor is connected to the upper surface of the L-shaped supporting seat through a bolt, and the end of the feeding auger penetrates through an inner ring coupler of the ball bearing and is connected to an output shaft of the feeding motor.

Preferably, a control valve is arranged on the right lower side of the discharge pipe, the mixing box is a cylindrical stainless steel box, and the mixing box is connected to the inner side of the supporting column through bolts.

Preferably, the upper vibration hammer is positioned in the middle of the lower part of the upper filter screen plate; the lower vibrating hammer is positioned in the middle of the lower part of the lower filter screen plate.

Preferably, the L-shaped supporting plate is connected to the lower position of the left side of the stirring tower through a bolt; the stirring shaft is transversely inserted at the lower side position in the stirring tower; and a stainless steel bearing is arranged at the intersection of the stirring shaft and the stirring tower.

Preferably, the connecting plate is a ring-shaped stainless steel plate; the connecting plate is connected to the lower part of the stirring tower through bolts.

Preferably, the lower end of the mortar buffer hopper is connected to the middle position of the upper surface of the mixing box through a bolt.

Preferably, the stirring tower is communicated with the interior of the mixing box through a mortar buffer hopper.

Preferably, the observation window is a round tempered glass window with the wall thickness of five to eight millimeters.

Preferably, the vibration motor is bolted at the lower side of the rear part of the outer surface of the stirring tower; the connecting rod and the supporting plate are respectively connected with the inner surface of the stirring tower through bolts.

Preferably, the power switch, the touch screen, the stirring motor, the vibrating motor and the feeding motor are respectively electrically connected with the control host.

Compared with the prior art, the method has the advantages that the mortar raw material is injected into the stirring tower through the sand material adding pipe and the liquid adding pipe, after being filtered by the upper filtering screen plate, the sand material is primarily stirred and mixed through the stirring motor, the stirring shaft, the connecting sleeve, the locking bolt and the stirring rod, and enters the mortar caching hopper after being filtered by the lower filtering screen plate, the sand material mixing condition is observed through the observation window, the discharge valve is opened to enter the mixing box, the feeding motor is started to drive the feeding auger to rotate, mixing and stirring are carried out again, the stirring efficiency is improved, the control valve of the discharge pipe is periodically opened to discharge materials, and in order to prevent the upper filtering screen plate and the lower filtering screen plate from being blocked, the vibration motor is started to drive the upper vibration hammer and the lower vibration hammer to vibrate and drain and dredge the slurry.

Drawings

Fig. 1 is a schematic structural view of the present invention.

Fig. 2 is a schematic structural diagram of a slurry guide hopper structure capable of being observed through filtering.

FIG. 3 is a schematic structural view of a mortar stirring shaft structure of the present invention.

Fig. 4 is a schematic structural view of the anti-blocking vibration hammer structure of the present invention.

FIG. 5 is a schematic structural diagram of a feed supplement mixing box structure of the present invention.

Fig. 6 is a schematic electrical wiring diagram of the present invention.

In the figure:

1. the device comprises a stirring tower, a sand material adding pipe, a liquid adding pipe, a supporting column, a filtering screen plate, an upper filtering screen plate, a manhole , a control box, a touch screen, a control host machine, a control box, a touch screen, a control host machine, a slurry guide hopper structure, a mortar buffer hopper, a connecting plate, a lower filtering screen plate, a mortar window, a mortar discharge valve, a mortar stirring shaft structure, a 111, an L-shaped supporting plate, a stirring motor, a stirring shaft, a 114, a connecting sleeve, a locking bolt, a 116, a stirring rod, an anti-blocking vibration hammer structure, a vibrating motor 121, a vibrating motor, a connecting rod, a 123, a supporting plate, a 124, an upper vibrating hammer, a 125, a lower vibrating hammer, a material supplementing and mixing box structure, a 131, a mixing box, a 132, a material supplementing hopper, a 133, a material pipe, a 134, an L-shaped supporting.

Detailed Description

The invention is further described with reference to the following figures:

example (b):

as shown in the accompanying drawings 1-2, the invention provides tower type mortar stirring device, which comprises a stirring tower 1, a mortar adding pipe 2, a liquid adding pipe 3, a support column 4, an upper filter screen plate 5, a manhole 6, a control box 7, a touch screen 8, a control host machine 9, a slurry guide hopper structure 10 capable of being observed in a filtering mode, a mortar stirring shaft structure 11, an anti-blocking vibration hammer structure 12, a material supplementing mixing box structure 13, a power switch 14 and a support base 15, wherein the mortar adding pipe 2 is embedded in the middle of the upper surface of the stirring tower 1, the liquid adding pipe 3 is embedded in the upper position of the right side of the stirring tower 1, ends of the support columns 4 are respectively bolted at four corners of the lower surface of the stirring tower 1, the other ends of the support columns are connected in the middle of the upper surface of the support base 15, the upper filter screen plate 5 is transversely bolted at the upper position of the inner side of the stirring tower 1, the 6 of the support column is hinged to the right position of the stirring tower 1, the buffer storage box 7 is connected to the front portion of the right side of the stirring tower 1, the buffer box structure, the buffer box 7 is connected to the upper portion of the buffer box structure, the buffer box 101, the buffer box structure of the buffer box 101, the buffer box structure is connected to the lower side of the buffer box structure, the buffer box structure 10, the buffer box structure, the buffer box 10 is connected to the buffer box structure, the buffer box structure 104 is connected to the buffer box structure, the buffer box structure 10 is connected to the buffer box structure, the buffer box structure 10, the buffer box structure 104 is connected to the lower side of the buffer box structure, the buffer box structure 10, the buffer box structure.

As shown in fig. 3, in this embodiment, specifically, the mortar stirring shaft structure 11 includes an L-shaped support plate 111, a stirring motor 112, a stirring shaft 113, a connecting sleeve 114, a locking bolt 115 and a stirring rod 116, where the stirring motor 112 is bolted to the upper surface of the L-shaped support plate 111; the shaft coupling of the stirring shaft 113 is connected to the output shaft of the stirring motor 112; the connecting sleeve 114 is sleeved on the outer surface of the stirring shaft 113 and is tightly supported and fixed by a locking bolt 115; the locking bolt 115 is in threaded connection with the middle position of the outer surface of the connecting sleeve 114; the stirring rods 116 are respectively bolted to the middle positions of the upper surface and the lower surface of the connecting sleeve 114.

As shown in fig. 4, in the present embodiment, specifically, the anti-blocking vibration hammer structure 12 includes a vibration motor 121, a connecting rod 122, a supporting plate 123, an upper vibration hammer 124 and a lower vibration hammer 125, an end of the connecting rod 122 is screwed to an output shaft of the vibration motor 121, an end of the connecting rod is respectively screwed to two upper and lower portions of a right side of the supporting plate 123, and the upper vibration hammer 124 and the lower vibration hammer 125 are respectively screwed to two upper and lower portions of a front surface of the supporting plate 123.

As shown in fig. 5, in this embodiment, specifically, the material supplementing and mixing box structure 13 includes a mixing box 131, a material supplementing hopper 132, a material discharging pipe 133, an L-shaped support 134, a ball bearing 135, a feeding motor 136 and a feeding auger 137, the material supplementing hopper 132 is bolted to the left side of the upper surface of the mixing box 131 and is communicated with the inside of the mixing box 131, the material discharging pipe 133 is bolted to the left side of the lower surface of the mixing box 131 and is communicated with the inside of the mixing box 131, the feeding motor 136 is bolted to the upper surface of the L-shaped support 134, and an inner ring coupler of the feeding auger 137 , which penetrates through the ball bearing 135, is connected to an output shaft of the feeding motor 136.

In this embodiment, a control valve is provided on the right lower side of the discharge pipe 133, the mixing box 131 is a cylindrical stainless steel box, and the mixing box 131 is bolted to the inner side of the support column 4.

In this embodiment, specifically, the upper vibration hammer 124 is located at the middle position of the lower part of the upper filter screen plate 5; the lower vibration hammer 125 is located at the middle position of the lower part of the lower filter screen plate 103.

In this embodiment, specifically, the L-shaped support plate 111 is bolted to the lower left side of the stirring tower 1; the stirring shaft 113 is transversely inserted into the lower side of the stirring tower 1; and a stainless steel bearing is arranged at the intersection of the stirring shaft 113 and the stirring tower 1.

In this embodiment, specifically, the connecting plate 102 is specifically made of an annular stainless steel plate; the connecting plate 102 is bolted to the lower part of the mixing tower 1.

In this embodiment, specifically, the lower end of the mortar buffer hopper 101 is bolted to the middle position of the upper surface of the mixing box 131.

In this embodiment, specifically, the stirring tower 1 is communicated with the interior of the mixing box 131 through the mortar buffer hopper 101.

In this embodiment, specifically, the observation window 104 is a circular tempered glass window with a wall thickness of five to eight millimeters.

In this embodiment, specifically, the vibration motor 121 is bolted to the lower position of the rear part of the outer surface of the stirring tower 1; the connecting rod 122 and the supporting plate 123 are respectively bolted to the inner surface of the stirring tower 1.

In this embodiment, specifically, the power switch 14, the touch screen 8, the stirring motor 112, the vibration motor 121, and the feeding motor 136 are respectively electrically connected to the control host 9.

In this embodiment, specifically, the power switch 14 is a switch of a type KCD 14; the touch screen 8 is a touch screen with model number of XTC; the stirring motor 112 is a motor with model number of YE 2; the vibration motor 121 is specifically a motor with a model number YZS 2; the feeding motor 136 is a motor with the model number of 2 IK; the control host 9 is a host with IPC-610 model.

Principle of operation

When the mortar mixing device is used, a raw material pipeline is respectively connected with a sand adding pipe 2 and a liquid adding pipe 3, an external power supply is switched on, mortar raw materials are injected into a stirring tower 1 through the sand adding pipe 2 and the liquid adding pipe 3, the mortar raw materials are filtered by an upper filtering screen plate 5, then are subjected to preliminary stirring and mixing through a stirring motor 112, a stirring shaft 113, a connecting sleeve 114, a locking bolt 115 and a stirring rod 116, are filtered by a lower filtering screen plate 103 and then enter a mortar cache hopper 101, the sand mixing condition is observed through an observation window 104, a discharge valve 105 is opened and enters a mixing box 131, a feeding motor 136 is started to drive a feeding auger 137 to rotate, mixing and stirring are carried out again, the stirring efficiency is improved, a control valve of a discharge pipe 133 is periodically opened to carry out, in order to prevent the upper filtering screen plate 5 and the lower filtering screen plate 103 from being blocked, a vibration motor 121 is started to drive a discharge hammer 124 and a lower vibration hammer 125 to vibrate, and fall and dredge the mortar.

The technical solutions of the present invention or similar technical solutions designed by those skilled in the art based on the teachings of the technical solutions of the present invention are all within the scope of the present invention.

Claims

The tower type mortar stirring device is characterized by comprising a stirring tower (1), a mortar adding pipe (2), a liquid adding pipe (3), a support column (4), an upper filtering screen plate (5), a manhole (6), a control box (7), a touch screen (8), a control host (9), a mortar guide hopper structure (10) capable of being observed through filtration, a mortar stirring shaft structure (11), an anti-blocking vibration hammer structure (12), a material supplementing mixing box structure (13), a power switch (14) and a support pad seat (15), wherein the mortar adding pipe (2) is embedded in the middle of the upper surface of the stirring tower (1), the liquid adding pipe (3) is embedded in the upper position of the right side of the stirring tower (1), the end of the support column (4) is respectively connected to the lower surface of the stirring tower (1) through a bolt, the other end of the support column (4) is connected to the middle position of the upper surface of the stirring tower (1) through a bolt, the bolt is connected to the middle position of the lower surface of the stirring tower (1), the middle position of the lower surface of the stirring tower (10) through a bolt, the middle bolt of the stirring screen box structure (10) is connected to the lower part of the stirring tower (1), the stirring screen box structure (10), the stirring screen box (10) is connected to the control board (10), the control board (10) and the control board (10) of the stirring box (10), the stirring box structure, the stirring box (10) capable of the stirring box structure, the stirring box structure is arranged on the stirring box (10), the stirring tower (10), the stirring box structure, the stirring box (10), the stirring box is connected to the hinge structure, the buffer memory 5) is connected to the buffer memory 5) and the buffer memory is connected to the buffer memory structure, the buffer.
2. The tower type mortar stirring device according to claim 1, wherein the mortar stirring shaft structure (11) comprises an L-shaped supporting plate (111), a stirring motor (112), a stirring shaft (113), a connecting sleeve (114), a locking bolt (115) and a stirring rod (116), wherein the stirring motor (112) is bolted on the upper surface of the L-shaped supporting plate (111); the shaft coupling of the stirring shaft (113) is connected to the output shaft of the stirring motor (112); the connecting sleeve (114) is sleeved on the outer surface of the stirring shaft (113) and is tightly supported and fixed by a locking bolt (115); the locking bolt (115) is in threaded connection with the middle position of the outer surface of the connecting sleeve (114); the stirring rod (116) is respectively bolted at the middle positions of the upper surface and the lower surface of the connecting sleeve (114).
3. The tower-type mortar mixing device according to claim 1, wherein the anti-blocking vibration hammer structure (12) comprises a vibration motor (121), a connecting rod (122), a supporting plate (123), an upper vibration hammer (124) and a lower vibration hammer (125), the end of the connecting rod (122) is screwed on the output shaft of the vibration motor (121), the other end is respectively bolted on the upper part and the lower part of the right side of the supporting plate (123), and the upper vibration hammer (124) and the lower vibration hammer (125) are respectively bolted on the upper part and the lower part of the front surface of the supporting plate (123).
4. The tower-type mortar stirring device according to claim 1, wherein the material supplementing and mixing box structure (13) comprises a mixing box (131), a material supplementing hopper (132), a material discharging pipe (133), an L-shaped supporting seat (134), a ball bearing (135), a feeding motor (136) and a feeding auger (137), the material supplementing hopper (132) is bolted at the left side position of the upper surface of the mixing box (131) and communicated with the inside of the mixing box (131), the material discharging pipe (133) is bolted at the left side position of the lower surface of the mixing box (131) and communicated with the inside of the mixing box (131), the feeding motor (136) is bolted at the upper surface of the L-shaped supporting seat (134), and the end of the feeding auger (137) penetrates through the inner ring coupling of the ball bearing (135) and is connected to the output shaft of the feeding motor (136).
5. The tower type mortar mixing device according to claim 4, wherein a control valve is arranged on the lower right side of the discharge pipe (133), the mixing box (131) is a cylindrical stainless steel box, and the mixing box (131) is bolted on the inner side of the supporting column (4).
6. The tower-type mortar mixing device according to claim 3, wherein the upper vibration hammer (124) is located at the lower middle position of the upper filter screen plate (5); the lower vibration hammer (125) is positioned in the middle of the lower part of the lower filter screen plate (103).
7. The tower-type mortar mixing device according to claim 2, wherein the L-shaped support plate (111) is bolted to the lower left side of the mixing tower (1); the stirring shaft (113) is transversely inserted into the lower side of the inside of the stirring tower (1); and a stainless steel bearing is arranged at the intersection of the stirring shaft (113) and the stirring tower (1).
8. The tower mortar mixing device according to claim 1, wherein the connecting plate (102) is a ring-shaped stainless steel plate; the connecting plate (102) is connected to the lower part of the stirring tower (1) through bolts.
9. A tower mortar mixing apparatus according to claim 4, wherein the mixing tower (1) is connected to the interior of the mixing tank (131) via a mortar buffer hopper (101).
10. The tower mortar mixing device of claim 1, wherein the observation window (104) is a round tempered glass window with a wall thickness of five to eight millimeters.