CN111550065B

CN111550065B - Hollow block grouting reinforcement equipment

Info

Publication number: CN111550065B
Application number: CN202010329334.9A
Authority: CN
Inventors: 黄�益
Original assignee: Guangdong Guangda Construction Group Co ltd
Current assignee: GUANGDONG GUANGDA CONSTRUCTION GROUP Co.,Ltd.
Priority date: 2020-04-23
Filing date: 2020-04-23
Publication date: 2021-12-03
Anticipated expiration: 2040-04-23
Also published as: CN111550065A

Abstract

The invention discloses grouting reinforcement equipment for hollow building blocks, which comprises a grouting shell and a grouting mechanism for grouting the hollow building blocks, wherein the grouting shell is of a cuboid structure, the grouting mechanism is arranged in the grouting shell, the grouting mechanism comprises a discharge pipe arranged on the grouting shell, an avoidance opening is formed in one side wall of the grouting shell, the discharge pipe can extend out of the avoidance opening of the grouting shell, a slurry pump body is arranged at the top of the grouting shell, an electromagnetic valve group is arranged on the wall part of the slurry pump body, the slurry pump body is communicated with the discharge pipe, the slurry pump body can supply slurry to the discharge pipe, when the hollow building blocks are grouted, the grouting shell is arranged at one side of the hollow building blocks, the discharge pipe of the grouting mechanism is positioned right above the hollow building blocks, the electromagnetic valve group is opened, and the slurry can flow into the discharge pipe through the slurry pump body, and then flows into the hollow block through the discharge pipe, thereby performing a grouting operation on the hollow block.

Description

Hollow block grouting reinforcement equipment

Technical Field

The invention relates to the technical field of building construction, in particular to hollow block grouting reinforcement equipment.

Background

The wall building block grout is mainly to grout the perps of building block, the perps grout of wall building block still relies on traditional manual mortar shovel operation at present, and traditional manual mortar shovel grout still has the grout not closely knit, the wall body is not firm, the problem that the gap is many, wall surface roughness can not satisfy common problems such as standard requirement, and during manual operation, need a large amount of labours, the construction progress is slower, it is many to fall to the ground the mortar during mortar crack pouring, it is more to fall to the ground the mortar when whitewashing the wall, cause the waste of work material, the unrestrained serious, engineering cost is high, and seriously influence engineering quality, for this reason, the grout equipment of hollow block is required.

Disclosure of Invention

In order to solve the defects of the prior art, the invention aims to provide grouting reinforcement equipment for hollow building blocks.

In order to achieve the technical purpose, the technical scheme adopted by the invention is as follows.

A hollow block grouting reinforcement apparatus, comprising:

grout casing, be used for carrying out the grout mechanism of grout to hollow block, grout casing be the cuboid structure, grout mechanism installs in grout casing, grout mechanism including installing row's material pipe on grout casing, a lateral wall department of grout casing has seted up and has dodged the opening, the opening of dodging of arranging the material pipe protractile grout casing, the top of grout casing be provided with the mud pump body, the wall portion of the mud pump body is provided with the electromagnetism valves, the mud pump body is put through with row's material pipe, the mud pump body can carry out the mud feed to row's material pipe.

As a further improvement of the technical scheme, the grouting mechanism comprises a first grouting assembly, a discharge pipe is arranged on the first grouting assembly, a lifting assembly used for adjusting the height of the grouting mechanism is arranged in the grouting shell, the lifting assembly comprises a lifting motor, a lifting screw rod, a first lifting guide rod, a second lifting guide rod, a third lifting guide rod, a mounting plate and a connecting plate, the lifting motor is mounted at the top of the grouting shell, an output shaft of the lifting motor vertically faces downwards and penetrates through the wall part of the grouting shell, one end of the lifting screw rod is fixedly connected with the output shaft end of the lifting motor in a coaxial mode, the other end of the lifting screw rod is movably connected with the bottom of the grouting shell, the first lifting guide rod, the second lifting guide rod and the third lifting guide rod are arranged on one side of the lifting screw rod in parallel, and the first lifting guide rod, The grout casing is arranged in four corners of second lift guide bar, third lift guide bar, lift lead screw branch, the mounting panel cover locate lift lead screw, third lift guide bar on, mounting panel and lift lead screw threaded connection, the connecting plate cover locate on first lift guide bar, second lift guide bar, grout mechanism install on mounting panel, connecting plate.

As a further improvement of this technical scheme, first grout subassembly still include flexible motor, flexible lead screw, sleeve, backup pad, flexible motor install on the mounting panel, the output shaft of flexible motor is the level and arranges and the face of perpendicular to mounting panel, the output shaft of flexible motor passes the face of mounting panel, the one end of flexible lead screw and the coaxial fixed connection of output shaft end of flexible motor, the other end of flexible lead screw stretches into to the sleeve in, flexible lead screw and sleeve threaded connection, sleeve, backup pad be parallel arrangement and structure as an organic whole, seted up the spout in the backup pad, the spout that the connecting plate passed the backup pad links to each other with the backup pad, the vertical tip that sets up in the backup pad of row's material pipe.

As a further improvement of the technical scheme, a sensor is arranged at the end part of the supporting plate and is a light curtain sensor.

As a further improvement of the technical scheme, a second grouting assembly, a third grouting assembly and a fourth grouting assembly are further arranged in the grouting shell, the structures of the second grouting assembly, the third grouting assembly and the fourth grouting assembly are the same as those of the first grouting assembly, and the first grouting assembly, the second grouting assembly, the third grouting assembly and the fourth grouting assembly are uniformly arranged on the mounting plate and the connecting plate.

As a further improvement of the technical scheme, the electromagnetic valve group comprises a first electromagnetic valve, a second electromagnetic valve, a third electromagnetic valve and a fourth electromagnetic valve, and the first electromagnetic valve, the second electromagnetic valve, the third electromagnetic valve and the fourth electromagnetic valve are respectively communicated with a discharge pipe on the first grouting assembly, the second grouting assembly, the third grouting assembly and the fourth grouting assembly.

As a further improvement of the technical scheme, the end part of the supporting plate is provided with a vibrating rod, and when the hollow building block is grouted, the vibrating rod can extend into the hollow building block.

As a further improvement of the technical scheme, the end part of the supporting plate is provided with a spray head which is communicated with a tap water pipe.

As a further improvement of the technical scheme, a sewage draining groove and a collecting shell are arranged in the grouting shell, the sewage draining groove is obliquely arranged and is positioned below the first grouting component, the second grouting component, the third grouting component and the fourth grouting component, and the collecting shell is positioned at the bottom of the grouting shell.

As a further improvement of the technical scheme, the bottom of the grouting shell is provided with universal wheels.

Compared with the prior art, the invention has the advantages that in the using process, when the hollow building block is grouted, the grouting shell is arranged at one side of the hollow building block, the discharge pipe of the grouting mechanism is positioned right above the hollow building block, then the electromagnetic valve group is opened, slurry can flow into the discharge pipe through the slurry pump body and then flows into the hollow building block through the discharge pipe, so that the hollow building block is grouted, the output shaft of the lifting motor rotates to drive the lifting screw rod to rotate, so that the grouting mechanism is driven to move up and down, the height of the grouting mechanism is adjusted, the output shaft of the telescopic motor can drive the telescopic screw rod to rotate, so that the sleeve is driven to move to the avoiding opening close to the grouting shell, then the support plate is driven to move to the avoiding opening close to the grouting shell, and the discharge pipe extends out of the hollow building block, thereby be convenient for grout hollow block, after the grout, flexible motor can drive row material pipe shrink to in the grout casing, when the tip of backup pad stretches out outside the grout casing, the sensor sends inductive signal and feeds back to the controller, controller control solenoid valve group opens, thereby be convenient for arrange material pipe supply mud, the vibrting spear can stretch into in the hollow building block, thereby make mud evenly distributed in the hollow building block, after the grout is accomplished, the shower nozzle can be to the vibrting spear, arrange the mud of row material pipe wall portion and wash, avoid mud to glue admittedly in the vibrting spear, arrange material pipe surface.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required to be used in the embodiments of the present invention will be briefly described below. It is obvious that the drawings described below are only some embodiments of the invention, and that for a person skilled in the art, other drawings can be derived from them without inventive effort.

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a schematic view of the inside of the grouting case of the present invention.

Fig. 3 is a schematic view of the inside of the grouting case of the present invention.

Fig. 4 is a schematic view of a first grouting assembly, a second grouting assembly, a third grouting assembly and a fourth grouting assembly according to the present invention.

Fig. 5 is a schematic view illustrating installation of a first grouting assembly, a second grouting assembly, a third grouting assembly, and a fourth grouting assembly according to the present invention.

Fig. 6 is a schematic view illustrating the installation of a first grouting assembly, a second grouting assembly, a third grouting assembly, and a fourth grouting assembly according to the present invention.

Fig. 7 is a schematic structural view of a first grout assembly of the present invention.

Fig. 8 is a schematic structural view of a first grout assembly of the present invention.

Labeled as:

10. grouting the shell; 110. a slurry pump body; 120. an electromagnetic valve group; 121. a first solenoid valve; 122. a second solenoid valve; 123. a third electromagnetic valve; 124. a fourth solenoid valve; 130. avoiding the opening; 140. a universal wheel; 150. a sewage draining groove; 160. a collection housing;

20. a grouting mechanism; 210. a first grout assembly; 211. a telescopic motor; 212. a telescopic screw rod; 213. a sleeve; 214. a support plate; 215. a discharge pipe; 216. a vibrating rod; 217. a sensor; 218. a spray head; 220. a second grout assembly; 230. a third grout assembly; 240. a fourth grout assembly;

30. a lifting assembly; 310. a lifting motor; 320. a lifting screw rod; 330. a first lifting guide bar; 340. a second lifting guide rod; 350. a third lifting guide rod; 360. mounting a plate; 370. a connecting plate.

Detailed Description

The technical scheme of the invention is further explained by the specific implementation mode in combination with the attached drawings.

Wherein the showings are for the purpose of illustration only and are shown by way of illustration only and not in actual form, and are not to be construed as limiting the present patent; to better illustrate the embodiments of the present invention, some parts of the drawings may be omitted, enlarged or reduced, and do not represent the size of an actual product; it will be understood by those skilled in the art that certain well-known structures in the drawings and descriptions thereof may be omitted.

The same or similar reference numerals in the drawings of the embodiments of the present invention correspond to the same or similar components; in the description of the present invention, it should be understood that if the terms "upper", "lower", "left", "right", "inner", "outer", etc. are used for indicating the orientation or positional relationship based on the orientation or positional relationship shown in the drawings, it is only for convenience of description and simplification of description, but it is not indicated or implied that the referred device or element must have a specific orientation, be constructed in a specific orientation and be operated, and therefore, the terms describing the positional relationship in the drawings are only used for illustrative purposes and are not to be construed as limitations of the present patent, and the specific meanings of the terms may be understood by those skilled in the art according to specific situations.

In the description of the present invention, unless otherwise explicitly specified or limited, the term "connected" or the like, if appearing to indicate a connection relationship between the components, is to be understood broadly, for example, as being fixed or detachable or integral; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or may be connected through one or more other components or may be in an interactive relationship with one another. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

As shown in fig. 1 to 8, a hollow block grouting reinforcement apparatus includes:

the grouting device comprises a grouting shell 10 and a grouting mechanism 20 used for grouting hollow building blocks, wherein the grouting shell 10 is of a cuboid structure, the grouting mechanism 20 is installed in the grouting shell 10, the grouting mechanism 20 comprises a discharge pipe 215 installed on the grouting shell 10, an avoiding opening 130 is formed in one side wall of the grouting shell 10, the discharge pipe 215 can extend out of the avoiding opening 130 of the grouting shell 10, a slurry pump body 110 is arranged at the top of the grouting shell 10, an electromagnetic valve group 120 is arranged on the wall of the slurry pump body 110, the slurry pump body 110 is communicated with the discharge pipe 215, the slurry pump body 110 can supply slurry to the discharge pipe 215, when the hollow building blocks are grouted, the grouting shell 10 is arranged on one side of the hollow building blocks, the discharge pipe 215 of the grouting mechanism 20 is positioned right above the hollow building blocks, the electromagnetic valve group 120 is opened, and the slurry can flow into the discharge pipe 215 through the slurry pump body 110, and then flows into the hollow block through the discharge pipe 215 to perform a grouting operation on the hollow block.

More specifically, the grouting mechanism 20 includes a first grouting assembly 210, a discharge pipe 215 is disposed on the first grouting assembly 210, and in order to be adapted to the height of the hollow building block, a lifting assembly 30 for adjusting the height of the grouting mechanism 20 is disposed in the grouting housing 10, the lifting assembly 30 includes a lifting motor 310, a lifting screw 320, a first lifting guide rod 330, a second lifting guide rod 340, a third lifting guide rod 350, a mounting plate 360, and a connecting plate 370, the lifting motor 310 is mounted at the top of the grouting housing 10, an output shaft of the lifting motor 310 vertically faces downward and passes through a wall portion of the grouting housing 10, one end of the lifting screw 320 is coaxially and fixedly connected with an output shaft end of the lifting motor 310, the other end of the lifting screw 320 is movably connected with the bottom of the grouting housing 10, and the first lifting guide rod 330, the second lifting guide rod 340, and the wall portion of the grouting housing 10 are movably connected with each other end of the grouting housing 10, Third lift guide bar 350 parallel arrangement is in one side of lifting screw 320, and first lift guide bar 330, second lift guide bar 340, third lift guide bar 350, lift lead screw 320 divide and arrange four corners of grout casing 10 in, 360 covers of mounting panel locate on lift lead screw 320, third lift guide bar 350, 360 and the 320 threaded connection of lift lead screw of mounting panel, connecting plate 370 cover locate on first lift guide bar 330, second lift guide bar 340, grout mechanism 20 install on mounting panel 360, connecting plate 370, the output shaft of elevator motor 310 rotates and drives lift lead screw 320 and rotate to drive grout mechanism 20 and reciprocate, thereby adjust the height of grout mechanism 20.

More specifically, in order to enable the discharge pipe 215 to freely contract in the grouting housing 10, that is, the discharge pipe 215 can extend out of the grouting housing 10 through the avoiding opening 130 of the grouting housing 10, the first grouting assembly 210 further includes a telescopic motor 211, a telescopic screw rod 212, a sleeve 213 and a support plate 214, the telescopic motor 211 is installed on the mounting plate 360, an output shaft of the telescopic motor 211 is horizontally arranged and perpendicular to a plate surface of the mounting plate 360, the output shaft of the telescopic motor 211 passes through the plate surface of the mounting plate 360, one end of the telescopic screw rod 212 is coaxially and fixedly connected with an output shaft end of the telescopic motor 211, the other end of the telescopic screw rod 212 extends into the sleeve 213, the telescopic screw rod 212 is in threaded connection with the sleeve 213, the sleeve 213 and the support plate 214 are arranged in parallel and are an integrated structure, the support plate 214 is provided with a chute, the connection plate 370 passes through the chute of the support plate 214 and is connected with the support plate 214, arrange the vertical tip that sets up in backup pad 214 of material pipe 215, the output shaft of flexible motor 211 rotates and can drive flexible lead screw 212 and rotate to drive sleeve 213 and remove to dodging opening 130 department that is close to grout casing 10, promote backup pad 214 and remove to dodging opening 130 department that is close to grout casing 10 after that, arrange material pipe 215 and stretch out outside grout casing 10, thereby be convenient for grout hollow block, after the grout, flexible motor 211 can drive to arrange material pipe 215 and shrink to in grout casing 10.

More specifically, the end of the supporting plate 214 is provided with a sensor 217, the sensor 217 is a light curtain sensor, when the end of the supporting plate 214 extends out of the grouting housing 10, the sensor 217 sends out a sensing signal and feeds the sensing signal back to the controller, and the controller controls the solenoid valve set 120 to be opened, so that slurry is conveniently supplied to the discharge pipe 215.

More specifically, a second grouting assembly 220, a third grouting assembly 230, and a fourth grouting assembly 240 are further disposed in the grouting housing 10, the second grouting assembly 220, the third grouting assembly 230, and the fourth grouting assembly 240 have the same structure as the first grouting assembly 210, the second grouting assembly 220, the third grouting assembly 230, and the fourth grouting assembly 240 are uniformly arranged on the mounting plate 360 and the connecting plate 370, and the first grouting assembly 210, the second grouting assembly 220, the third grouting assembly 230, and the fourth grouting assembly 240 can simultaneously grout the hollow block, thereby improving grouting efficiency.

More specifically, the electromagnetic valve group 120 includes a first electromagnetic valve 121, a second electromagnetic valve 122, a third electromagnetic valve 123, and a fourth electromagnetic valve 124, and the first electromagnetic valve 121, the second electromagnetic valve 122, the third electromagnetic valve 123, and the fourth electromagnetic valve 124 are respectively connected to a discharge pipe 215 on the first grouting assembly 210, the second grouting assembly 220, the third grouting assembly 230, and the fourth grouting assembly 240, so that the discharge pipe 215 on the first grouting assembly 210, the second grouting assembly 220, the third grouting assembly 230, and the fourth grouting assembly 240 can be respectively controlled to discharge, thereby facilitating grouting of the hollow block.

More specifically, the end of the supporting plate 214 is provided with a vibrating rod 216, and when the hollow building block is grouted, the vibrating rod 216 can extend into the hollow building block, so that the slurry is uniformly distributed in the hollow building block.

More specifically, the end of the support plate 214 is provided with a nozzle 218, the nozzle 218 is connected with a tap water pipe, the nozzle 218 can spray water to the vibrating rod 216 and the discharge pipe 215, and after grouting is completed, the nozzle 218 can flush slurry on the wall of the vibrating rod 216 and the wall of the discharge pipe 215, so that the slurry is prevented from being adhered to the surface of the vibrating rod 216 and the surface of the discharge pipe 215.

More specifically, a sewage draining groove 150 and a collecting housing 160 are arranged in the grouting housing 10, the sewage draining groove 150 is arranged in an inclined manner and is positioned below the first grouting assembly 210, the second grouting assembly 220, the third grouting assembly 230 and the fourth grouting assembly 240, the collecting housing 160 is positioned at the bottom of the grouting housing 10, and muddy water flushed by tap water can flow into the collecting housing 160 through the sewage draining groove 150.

More specifically, the bottom of the grouting housing 10 is provided with universal wheels 140, which facilitates movement of the grouting housing 10.

The working principle is as follows:

in the use process of the invention, when the hollow building block is grouted, the grouting shell 10 is arranged at one side of the hollow building block, the discharge pipe 215 of the grouting mechanism 20 is positioned right above the hollow building block, then the electromagnetic valve group 120 is opened, the slurry can flow into the discharge pipe 215 through the slurry pump body 110 and then flow into the hollow building block through the discharge pipe 215, so that the grouting operation is carried out on the hollow building block, the output shaft of the lifting motor 310 rotates to drive the lifting screw rod 320 to rotate, so as to drive the grouting mechanism 20 to move up and down, so as to adjust the height of the grouting mechanism 20, the output shaft of the telescopic motor 211 rotates to drive the telescopic screw rod 212 to rotate, so as to drive the sleeve 213 to move to the avoiding opening 130 close to the grouting shell 10, then the support plate 214 is pushed to move to the avoiding opening 130 close to the grouting shell 10, and the discharge pipe 215 extends out of the grouting shell 10, thereby be convenient for grout hollow block, after the grout, flexible motor 211 can drive row material pipe 215 and contract to in the grout casing 10, when the tip of backup pad 214 stretches out outside grout casing 10, sensor 217 sends inductive signal and feeds back to the controller, controller control solenoid valve group 120 is opened, thereby be convenient for supply mud to row material pipe 215, vibrting spear 216 can stretch into in the hollow brickwork, thereby make mud evenly distributed in the hollow brickwork, after the grout is accomplished, shower nozzle 218 can be to vibrting spear 216, the mud of arranging material pipe 215 wall portion washes, avoid mud to glue admittedly in vibrting spear 216, arrange material pipe 215 surface.

It should be understood that the above-described embodiments are merely preferred embodiments of the invention and the technical principles applied thereto. It will be understood by those skilled in the art that various modifications, equivalents, changes, and the like can be made to the present invention. However, such variations are within the scope of the invention as long as they do not depart from the spirit of the invention. In addition, certain terms used in the specification and claims of the present application are not limiting, but are used merely for convenience of description.

Claims

1. The utility model provides a hollow block reinforcing apparatus that is in milk which characterized in that, it includes:

the grouting structure comprises a grouting shell (10) and a grouting mechanism (20) used for grouting hollow building blocks, wherein the grouting shell (10) is of a cuboid structure, the grouting mechanism (20) is installed in the grouting shell (10), the grouting mechanism (20) comprises a discharge pipe (215) installed on the grouting shell (10), an avoiding opening (130) is formed in one side wall of the grouting shell (10), the discharge pipe (215) can extend out of the avoiding opening (130) of the grouting shell (10), a slurry pump body (110) is arranged at the top of the grouting shell (10), an electromagnetic valve group (120) is arranged on the wall of the slurry pump body (110), the slurry pump body (110) is communicated with the discharge pipe (215), and the slurry pump body (110) can supply slurry to the discharge pipe (215);

the grouting mechanism (20) comprises a first grouting assembly (210), a discharge pipe (215) is arranged on the first grouting assembly (210), a lifting assembly (30) used for adjusting the height of the grouting mechanism (20) is arranged in a grouting shell (10), the lifting assembly (30) comprises a lifting motor (310), a lifting screw rod (320), a first lifting guide rod (330), a second lifting guide rod (340), a third lifting guide rod (350), a mounting plate (360) and a connecting plate (370), the lifting motor (310) is mounted at the top of the grouting shell (10), an output shaft of the lifting motor (310) vertically downwards penetrates through the wall part of the grouting shell (10), one end of the lifting screw rod (320) is coaxially and fixedly connected with the output shaft end of the lifting motor (310), the other end of the lifting screw rod (320) is movably connected with the bottom of the grouting shell (10), the grouting device comprises a grouting shell (10), a first lifting guide rod (330), a second lifting guide rod (340) and a third lifting guide rod (350), wherein the first lifting guide rod (330), the second lifting guide rod (340) and the third lifting guide rod (350) are arranged on one side of the lifting screw rod (320) in parallel, the first lifting guide rod (330), the second lifting guide rod (340), the third lifting guide rod (350) and the lifting screw rod (320) are respectively arranged at four corners of the grouting shell (10), a mounting plate (360) is sleeved on the lifting screw rod (320) and the third lifting guide rod (350), the mounting plate (360) is in threaded connection with the lifting screw rod (320), a connecting plate (370) is sleeved on the first lifting guide rod (330) and the second lifting guide rod (340), and a grouting mechanism (20) is arranged on the mounting plate (360) and the connecting plate (370);

the first grouting assembly (210) further comprises a telescopic motor (211), a telescopic screw rod (212), a sleeve (213) and a support plate (214), the telescopic motor (211) is installed on the mounting plate (360), an output shaft of the telescopic motor (211) is horizontally arranged and perpendicular to the surface of the mounting plate (360), the output shaft of the telescopic motor (211) penetrates through the surface of the mounting plate (360), one end of the telescopic screw rod (212) is coaxially and fixedly connected with the output shaft end of the telescopic motor (211), the other end of the telescopic screw rod (212) extends into the sleeve (213), the telescopic screw rod (212) is in threaded connection with the sleeve (213), the sleeve (213) and the support plate (214) are arranged in parallel and are of an integrated structure, a sliding groove is formed in the support plate (214), and the connecting plate (370) penetrates through the sliding groove of the support plate (214) to be connected with the support plate (214), the discharge pipe (215) is vertically arranged at the end part of the supporting plate (214);

a sensor (217) is arranged at the end part of the supporting plate (214), and the sensor (217) is a light curtain sensor (217);

the grouting shell (10) is also internally provided with a second grouting assembly (220), a third grouting assembly (230) and a fourth grouting assembly (240), the structures of the second grouting assembly (220), the third grouting assembly (230) and the fourth grouting assembly (240) are the same as those of the first grouting assembly (210), and the first grouting assembly (210), the second grouting assembly (220), the third grouting assembly (230) and the fourth grouting assembly (240) are uniformly arranged on the mounting plate (360) and the connecting plate (370);

the electromagnetic valve group (120) comprises a first electromagnetic valve (121), a second electromagnetic valve (122), a third electromagnetic valve (123) and a fourth electromagnetic valve (124), wherein the first electromagnetic valve (121), the second electromagnetic valve (122), the third electromagnetic valve (123) and the fourth electromagnetic valve (124) are respectively communicated with a discharge pipe (215) on the first grouting assembly (210), the second grouting assembly (220), the third grouting assembly (230) and the fourth grouting assembly (240);

the end part of the supporting plate (214) is provided with a vibrating rod (216), and when the hollow building block is grouted, the vibrating rod (216) can extend into the hollow building block;

the end part of the supporting plate (214) is provided with a spray head (218), and the spray head (218) is communicated with a tap water pipe;

a sewage discharge groove (150) and a collection shell (160) are arranged in the grouting shell (10), the sewage discharge groove (150) is obliquely arranged and is positioned below the first grouting component (210), the second grouting component (220), the third grouting component (230) and the fourth grouting component (240), and the collection shell (160) is positioned at the bottom of the grouting shell (10);

the bottom of the grouting shell (10) is provided with universal wheels (140).