CN111744418A

CN111744418A - Building cement mixing apparatus

Info

Publication number: CN111744418A
Application number: CN202010649462.1A
Authority: CN
Inventors: 韩宝芹
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-07-08
Filing date: 2020-07-08
Publication date: 2020-10-09

Abstract

The invention relates to the field of buildings, in particular to building cement mixing equipment. The carrying of stones can be realized; meanwhile, the using length of the carrying belt can be adjusted according to the actual condition, so that the carrying belt is convenient to adapt to different using conditions; the crushing and mixing of stone materials can be realized; the crushing effect can be adjusted according to the actual situation; can automatically discharge materials. Including the delivery assembly, smash the assembly, arrange the material assembly, the loading board slides to the downside along lower extreme sleeve pipe, and then make the loading board drive the lower extreme rotary column and move down, and then make and drive one and move down of lower extreme awl tooth, and then make two meshing transmissions of lower extreme awl tooth and lower extreme awl tooth, start two external supporting motor C of lower extreme awl tooth simultaneously, and then drive two rotations of lower extreme awl tooth, and then drive through two of lower extreme awl teeth and arrange the rotation of material rotor blade, simultaneously through arranging the contact of material rotor blade and cement, and then make during cement passes through the rectangle through-hole and flows into the intercommunication sleeve pipe, and then realize arranging the material to the automation of cement.

Description

Building cement mixing apparatus

Technical Field

The invention relates to the field of buildings, in particular to building cement mixing equipment.

Background

The building cement mixing equipment is a common equipment in the field of buildings, but the common building cement mixing equipment has single function.

Disclosure of Invention

The invention aims to provide building cement mixing equipment which can carry stone; meanwhile, the using length of the carrying belt can be adjusted according to the actual condition, so that the carrying belt is convenient to adapt to different using conditions; the crushing and mixing of stone materials can be realized; the crushing effect can be adjusted according to the actual situation; can automatically discharge materials.

The purpose of the invention is realized by the following technical scheme:

the utility model provides a building cement mixing apparatus, includes delivery assembly, smashes assembly, row's material assembly which characterized in that: the carrying assembly is connected with the crushing assembly, and the crushing assembly is connected with the discharging assembly.

As a further optimization of the technical scheme, the invention relates to building cement mixing equipment, which comprises a carrying assembly, an upper end sleeve, an upper end transmission rod, a carrying belt, an upper end sliding frame I, a roller I, an upper end sliding frame II, a roller III, a roller IV, a roller V, an upper end clamping groove I, an upper end clamp push spring I, an arc-shaped rod I, a transmission ball I, an arc-shaped rod II, a transmission ball II, an arc-shaped rod III and an arc-shaped rod IV, wherein the upper end sliding frame I is fixedly connected with the upper end sleeve, the roller I is rotatably connected with the upper end sliding frame, the roller V is rotatably connected with the upper end sliding frame I, the roller II, the roller III, the roller IV is rotatably connected with the upper end sliding frame II, the upper end clamping groove I is arranged on the upper end sliding frame II, the upper end clamping groove I is slidably connected with the upper end sliding frame I, the upper end clamping groove I, the upper end clamp push spring I is arranged between the upper end clamp I and the upper end sliding frame I, the arc-shaped rod I is connected with the transmission ball I in a sliding fit mode, the transmission ball I is connected with the arc-shaped rod II in a sliding fit mode, the arc-shaped rod II is fixedly connected with the upper end transmission rod, the upper end transmission rod is fixedly connected with the arc-shaped rod II in a sliding fit mode, the arc-shaped rod II is connected with the transmission ball II in a sliding fit mode, the transmission ball II is connected with the arc-shaped rod III in a sliding fit mode, the upper end sliding frame I is fixedly connected with the roller I, the roller I is provided with a plurality of rollers, the.

As a further optimization of the technical scheme, the building cement mixing device comprises a middle-end sleeve, a first arc-shaped hinged rod, a second arc-shaped hinged rod, a third arc-shaped hinged rod, a fourth arc-shaped hinged rod, a fifth arc-shaped hinged rod, a first middle-end rotating column, a middle-end fixed support, an eccentric rotating rod, a driving rack rod, a first middle-end pushing spring, a rectangular middle-end slider, an upper-end limiting rectangular block, a second middle-end pushing spring, a middle-end rotating column, crushing blades, blade hinged rods, a sliding sleeve, a spherical middle-end clamping groove, a spherical middle-end pushing spring, a spherical middle-end clamping rod, a prismatic clamping rod and a prismatic clamping rod pushing spring, wherein the first middle-end rotating column is rotatably connected with the middle-end sleeve, the first arc-shaped hinged rod is fixedly connected with the first middle-end rotating column, the first arc-shaped hinged rod is rotatably connected with the second arc-shaped hinged rod, the second arc-shaped hinged rod is rotatably connected with the third arc-shaped hinged rod, the, the four arc-shaped hinged rods are rotatably connected with the five arc-shaped hinged rods, the five arc-shaped hinged rods are fixedly connected with other middle-end rotary columns, a plurality of middle-end rotary columns are arranged on the first arc-shaped hinged rods, the middle-end fixed support is fixedly connected with the middle-end sleeve, the first middle-end rotary column is rotatably connected with the middle-end fixed support, the eccentric rotary rod is fixedly connected with the first middle-end rotary column, the driving rack rod is slidably connected with the eccentric rotary rod, a clamping groove A is arranged on the eccentric rotary rod, the prismatic clamping rod is slidably connected with the driving rack rod, a prismatic clamping spring is arranged between the prismatic clamping rod and the driving rack rod, the prismatic clamping rod is matched and connected with the clamping groove A arranged on the eccentric rotary rod, a middle-end rectangular slider is slidably connected with the driving rack rod, a middle-end pushing spring is sleeved and connected with the driving rack rod, a middle-end rectangular slider is arranged between the two middle-end pushing springs, an upper-end limiting rectangular block is fixedly connected with the driving rack rod, and a, the middle-end push spring II is connected with the middle-end fixed support in a sleeved mode, the middle-end push spring II is arranged between the two middle-end rectangular sliders, the middle-end rotary column is rotatably connected with the middle-end fixed support, the driving rack rod is in meshed transmission with the middle-end rotary column, the middle-end spherical push spring is arranged on the middle-end rotary column, the crushing blade is rotatably connected with the middle-end rotary column, the blade hinge rod is hinged to the crushing blade, the blade hinge rod is hinged to the sliding sleeve, the middle-end spherical clamp rod is slidably connected with the sliding sleeve, the middle-end spherical push spring is arranged between the middle-end spherical clamp rod and the sliding sleeve, the middle-end spherical clamp rod is connected with the middle-end spherical clamp groove in a matched mode, the middle-end sleeve is fixedly connected with the upper-end sleeve, and the middle-.

As a further optimization of the technical scheme, the invention relates to building cement mixing equipment, wherein a discharge assembly comprises a lower end sleeve, a bearing plate, a communicating sleeve, a lower end cover, a lower end rotary column, an inner end spring, a first lower end bevel gear, a second lower end bevel gear, a discharge rotating blade and a rectangular through hole, the bearing plate is connected with the lower end sleeve in a sliding manner, the communicating sleeve is connected with the bearing plate in a sliding manner, the communicating sleeve is fixedly connected with the lower end sleeve, the rectangular through hole is arranged on the communicating sleeve, the lower end cover is fixedly connected with the communicating sleeve, the discharge rotating blade is connected with the lower end cover in a rotating manner, the second lower end bevel gear is fixedly connected with the discharge rotating blade, the lower end rotary column is connected with the bearing plate in a rotating manner, the lower end rotary column is connected with the lower end sleeve in a sliding manner, the inner end spring is sleeved with the lower, the lower end sleeve is fixedly connected with the middle end sleeve, and the second lower end bevel gear is externally connected with a matched motor C.

The building cement mixing equipment has the beneficial effects that:

according to the building cement mixing device, as the mass of cement in the device is increased, the bearing plate slides downwards along the lower end sleeve, the bearing plate drives the lower end rotary column to move downwards, the lower end bevel gear is driven to move downwards, the lower end bevel gear I is in meshing transmission with the lower end bevel gear II, a matching motor C externally connected with the lower end bevel gear II is started simultaneously, the lower end bevel gear II is driven to rotate, the discharging rotating blades are driven to rotate by the lower end bevel gear II, cement flows into the communicating sleeve through the rectangular through holes simultaneously through the contact between the discharging rotating blades and the cement, and then the cement is discharged automatically.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a first general structural diagram of the present invention;

FIG. 2 is a second overall structural schematic of the present invention;

FIG. 3 is a first schematic structural view of the carrying assembly 1 of the present invention;

FIG. 4 is a schematic structural view II of the carrying assembly 1 of the present invention;

FIG. 5 is a schematic view of the structure of the carrying assembly 1 of the present invention;

FIG. 6 is a fourth schematic structural view of the carrying assembly 1 of the present invention;

FIG. 7 is a schematic structural view of the carrying assembly 1 of the present invention;

FIG. 8 is a first schematic view of the comminution assembly 2 of the present invention;

FIG. 9 is a second schematic structural view of the comminution assembly 2 of the present invention;

FIG. 10 is a third schematic view of the comminution assembly 2 of the present invention;

FIG. 11 is a fourth schematic view of the comminution assembly 2 according to the invention;

FIG. 12 is a fifth schematic view of the comminution assembly 2 of the present invention;

figure 13 is a sixth schematic view of the comminution assembly 2 of the invention;

FIG. 14 is a first schematic view of the discharge assembly 3 of the present invention;

fig. 15 is a schematic structural diagram of the discharge assembly 3 of the present invention.

In the figure: a carrying assembly 1; an upper end sleeve 1-1; an upper end transmission rod 1-2; a carrier belt 1-3; 1-4 of an upper end sliding frame; 1-5 of a roller I; 1-6 of an upper end sliding frame II; a second roller 1-7; 1-8 parts of roller III; rollers four 1-9; 1-10 of a roller; 1-11 of an upper end clamping groove; 1-12 of an upper end clip; the upper end clamp pushes the spring 1-13; 1-14 of an arc-shaped rod I; 1-15 parts of a first transmission ball; 1-16 of a second arc rod; a second driving ball 1-17; 1-18 of arc-shaped rods; 1-19 of arc-shaped rod; a crushing assembly 2; 2-1 of a middle sleeve; 2-2 parts of an arc-shaped hinge rod; 2-3 of an arc-shaped hinge rod; arc-shaped hinge rods III 2-4; 2-5 of arc-shaped hinge rods; five arc-shaped hinge rods 2-6; 2-7 of a middle-end rotating column I; 2-8 of a middle-end fixed support; 2-9 parts of an eccentric rotating rod; driving the rack bar 2-10; a middle end push spring I is 2-11; 2-12 of middle-end rectangular sliders; the upper end limit rectangular block is 2-13; a middle end push spring II 2-14; 2-15 of middle-end rotary column; 2-16 parts of crushing blades; blade hinge rods 2-17; sliding sleeves 2-18; 2-19 of a middle spherical clamping groove; 2-20 parts of middle-end spherical push spring; 2-21 parts of a middle spherical clamping rod; 2-22 of prismatic clamping rod; a prismatic clamping rod push spring 2-23; a discharge assembly 3; a lower end sleeve 3-1; a carrier plate 3-2; 3-3 of a communicating sleeve; 3-4 parts of a lower end cover; 3-5 of a lower end rotary column; inner end springs 3-6; 3-7 parts of lower end bevel gear I; 3-8 parts of lower end bevel gear II; discharging rotating blades 3-9; rectangular through holes 3-10.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The fixed connection in the device is realized by fixing in modes of welding, thread fixing and the like, and different fixing modes are used in combination with different use environments; the rotary connection means that the bearing is arranged on the shaft in a drying mode, a spring retainer ring groove is formed in the shaft or the shaft hole, and the elastic retainer ring is clamped in the retainer ring groove to achieve axial fixation of the bearing and achieve rotation; the sliding connection refers to the connection through the sliding of the sliding block in the sliding groove or the guide rail, and the sliding groove or the guide rail is generally in a step shape, so that the sliding block is prevented from falling off in the sliding groove or the guide rail; the hinge joint is a movable connection mode on connecting parts such as a hinge, a pin shaft, a short shaft and the like; the required sealing positions are sealed by sealing rings or O-shaped rings.

The first embodiment is as follows:

the present embodiment is described below with reference to fig. 1 to 15, and a construction cement mixing apparatus includes a carrying assembly 1, a pulverizing assembly 2, and a discharging assembly 3, and is characterized in that: the carrying assembly 1 is connected with the crushing assembly 2, and the crushing assembly 2 is connected with the discharging assembly 3.

The second embodiment is as follows:

the first embodiment is further described with reference to fig. 1-15, the carrying assembly 1 includes an upper end sleeve 1-1, an upper end transmission rod 1-2, a carrying belt 1-3, an upper end carriage 1-4, a roller 1-5, an upper end carriage two 1-6, a roller two 1-7, a roller three 1-8, a roller four 1-9, a roller five 1-10, an upper end slot one 1-11, an upper end clip one 1-12, an upper end clip push spring one 1-13, an arc rod one 1-14, a transmission ball one 1-15, an arc rod two 1-16, a transmission ball two 1-17, an arc rod three 1-18, an arc rod four 1-19, an upper end carriage one 1-4 is fixedly connected with the upper end sleeve 1-1, the roller I1-5 is rotatably connected with the upper end sliding frame I1-4, the roller V1-10 is rotatably connected with the upper end sliding frame I1-4, the roller II 1-7, the roller III 1-8 and the roller IV 1-9 are rotatably connected with the upper end sliding frame II 1-6, the upper end sliding frame I1-4 is slidably connected with the upper end sliding frame II 1-6, the upper end clamping groove I1-11 is arranged on the end sliding frame II 1-6, the upper end clamp I1-12 is slidably connected with the upper end sliding frame I1-4, the upper end clamp I1-12 is matched and connected with the upper end clamping groove I1-11, the upper end clamp push spring I1-13 is arranged between the upper end clamp I1-12 and the upper end sliding frame I1-4, the arc-shaped rod I1-14 is slidably matched and connected with the transmission ball I1-15, the first driving balls 1-15 are connected with the second arc-shaped rods 1-16 in a sliding fit mode, the second arc-shaped rods 1-16 are fixedly connected with the first upper driving rods 1-2, the first upper driving rods 1-2 are fixedly connected with the fourth arc-shaped rods 1-19, the fourth arc-shaped rods 1-19 are connected with the second driving balls 1-17 in a sliding fit mode, the second driving balls 1-17 are connected with the third arc-shaped rods 1-18 in a sliding fit mode, the first upper sliding frames 1-4 are fixedly connected with the first rollers 1-5, the first rollers 1-5 are provided with a plurality of rollers, the fourth arc-shaped rods 1-19 are fixedly connected with the first other rollers 1-5, and the second rollers 1-7 are externally connected with matched motors A.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1-15, and the embodiment further describes the first embodiment, wherein the crushing assembly 2 comprises a middle end sleeve 2-1, a first arc-shaped hinged rod 2-2, a second arc-shaped hinged rod 2-3, a third arc-shaped hinged rod 2-4, a fourth arc-shaped hinged rod 2-5, a fifth arc-shaped hinged rod 2-6, a first middle end rotary column 2-7, a middle end fixing bracket 2-8, an eccentric rotary rod 2-9, a driving rack rod 2-10, a first middle end push spring 2-11, a middle end rectangular slider 2-12, a upper end limiting rectangular block 2-13, a second middle end push spring 2-14, a middle end rotary column 2-15, crushing blades 2-16, blade hinged rods 2-17, a sliding sleeve 2-18, a middle end spherical clamping groove 2-19, a first spherical clamping groove 2-19, a second clamping groove 2-14, a second clamping groove 2, A middle end spherical push spring 2-20, a middle end spherical clamping rod 2-21, a prismatic clamping rod 2-22 and a prismatic clamping rod push spring 2-23, wherein a middle end rotary column I2-7 is rotationally connected with a middle end sleeve 2-1, an arc-shaped hinge rod I2-2 is fixedly connected with the middle end rotary column I2-7, an arc-shaped hinge rod I2-2 is rotationally connected with an arc-shaped hinge rod II 2-3, an arc-shaped hinge rod II 2-3 is rotationally connected with an arc-shaped hinge rod III 2-4, an arc-shaped hinge rod III 2-4 is rotationally connected with an arc-shaped hinge rod IV 2-5, an arc-shaped hinge rod IV 2-5 is rotationally connected with an arc-shaped hinge rod V2-6, an arc-shaped hinge rod V2-6 is fixedly connected with other middle end rotary columns I2-7, a plurality of middle end rotary columns I2-7 are arranged, a middle end fixing supports 2-8 are fixedly connected with the middle end sleeve 2-1, the middle end rotary column I2-7 is rotatably connected with the middle end fixed support 2-8, the eccentric rotary rod 2-9 is fixedly connected with the middle end rotary column I2-7, the driving rack rod 2-10 is slidably connected with the eccentric rotary rod 2-9, the eccentric rotary rod 2-9 is provided with a clamping groove A, the prismatic clamping rod 2-22 is slidably connected with the driving rack rod 2-10, the prismatic clamping rod push spring 2-23 is arranged between the prismatic clamping rod 2-22 and the driving rack rod 2-10, the prismatic clamping rod 2-22 is matched and connected with the clamping groove A arranged on the eccentric rotary rod 2-9, the middle end rectangular slider 2-12 is slidably connected with the driving rack rod 2-10, the middle end push spring I2-11 is sleeved and connected with the driving rack rod 2-10, the middle end rectangular slider 2-12 is arranged between the two middle end push springs I2-11, the upper end limiting rectangular block 2-13 is fixedly connected with the driving rack bar 2-10, the middle end rectangular slider 2-12 is connected with the middle end fixed bracket 2-8 in a sliding way, the middle end push spring II 2-14 is connected with the middle end fixed bracket 2-8 in a sleeved way, the middle end push spring II 2-14 is arranged between the two middle end rectangular sliders 2-12, the middle end rotary column 2-15 is connected with the middle end fixed bracket 2-8 in a rotating way, the driving rack bar 2-10 is in meshing transmission with the middle end rotary column 2-15, the middle end spherical clamping groove 2-19 is arranged on the middle end rotary column 2-15, the crushing blade 2-16 is connected with the middle end rotary column 2-15 in a rotating way, the blade hinge bar 2-17 is connected with the crushing blade 2-16 in a hinged way, the blade hinge bar 2-17 is connected with the sliding sleeve 2-18 in a hinged way, the middle end spherical clamping rod 2-21 is connected with the sliding sleeve 2-18 in a sliding mode, the middle end spherical push spring 2-20 is arranged between the middle end spherical clamping rod 2-21 and the sliding sleeve 2-18, the middle end spherical clamping rod 2-21 is connected with the middle end spherical clamping groove 2-19 in a matching mode, the middle end sleeve 2-1 is fixedly connected with the upper end sleeve 1-1, and the middle end rotating column I2-7 is externally connected with a matched motor B.

The fourth concrete implementation mode:

the present embodiment is described below with reference to fig. 1-15, and the present embodiment further describes the first embodiment, wherein the discharge assembly 3 includes a lower end sleeve 3-1, a bearing plate 3-2, a communication sleeve 3-3, a lower end cap 3-4, a lower end rotary column 3-5, an inner end spring 3-6, a lower end bevel gear 3-7, a lower end bevel gear two 3-8, a discharge rotating blade 3-9, and a rectangular through hole 3-10, the bearing plate 3-2 is slidably connected to the lower end sleeve 3-1, the communication sleeve 3-3 is slidably connected to the bearing plate 3-2, the communication sleeve 3-3 is fixedly connected to the lower end sleeve 3-1, the rectangular through hole 3-10 is disposed on the communication sleeve 3-3, and the lower end cap 3-4 is fixedly connected to the communication sleeve 3-3, the discharging rotating blade 3-9 is rotatably connected with the lower end cover 3-4, the lower end bevel gear II 3-8 is fixedly connected with the discharging rotating blade 3-9, the lower end rotary column 3-5 is rotatably connected with the bearing plate 3-2, the lower end rotary column 3-5 is slidably connected with the lower end sleeve 3-1, the inner end spring 3-6 is connected with the lower end rotary column 3-5 in a sleeved mode, the inner end spring 3-6 is arranged between the bearing plate 3-2 and the lower end sleeve 3-1, the lower end bevel gear I3-7 is fixedly connected with the lower end rotary column 3-5, the lower end sleeve 3-1 is fixedly connected with the middle end sleeve 2-1, and the lower end bevel gear II 3-8 is externally connected with a matched motor C;

along with the increase of the mass of the cement in the device, the bearing plate 3-2 slides downwards along the lower end sleeve 3-1, the bearing plate 3-2 drives the lower end rotating column 3-5 to move downwards, the lower end bevel gear 3-7 is driven to be in meshed transmission with the lower end bevel gear two 3-8, a matched motor C externally connected with the lower end bevel gear two 3-8 is started, the lower end bevel gear two 3-8 is driven to rotate, the discharging rotating blade 3-9 is driven to rotate through the lower end bevel gear two 3-8, the cement is contacted with the cement through the discharging rotating blade 3-9, the cement flows into the communicating sleeve 3-3 through the rectangular through hole 3-10 and flows out through the communicating sleeve 3-3, thereby realizing the automatic discharge of the cement.

The invention relates to a building cement mixing device, which has the working principle that:

when the stone material processing device is used, a matched motor A externally connected with the rollers II 1-7 is started, the rollers II 1-7 are driven to rotate, the carrying belts 1-3 are driven by the rollers II 1-7, stone materials to be processed are placed on the carrying belts 1-3, and carrying of the stone materials is achieved through the carrying belts 1-3; meanwhile, in order to adapt to different use conditions, the upper end sliding frame II 1-6 is slid along the upper end sliding frame I1-4, so that the total length of the upper end sliding frame II 1-6 and the upper end sliding frame I1-4 is changed, and different use conditions are conveniently adapted; when the upper end sliding frame II 1-6 and the upper end sliding frame I1-4 slide relatively, the distance between the upper end sliding frame II 1-6 and the upper end sliding frame I1-4 which slides relatively is compensated through the change of the displacement distance between the roller IV 1-9 and the roller V1-10, so that the carrying belt 1-3 is in a tensioning state, and sand grains are conveniently carried; starting a matched motor B connected with the middle rotary column I2-7 to drive the middle rotary column I2-7 to rotate, further driving an eccentric rotary rod 2-9 to rotate, further driving a driving rack rod 2-10 to rotate through the eccentric rotary rod 2-9, further driving a middle rotary column 2-15 to rotate in a reciprocating mode through the driving rack rod 2-10, further driving a crushing blade 2-16 to move through the middle rotary column 2-15, and further crushing stone through the contact of the crushing blade 2-16 and the stone, and simultaneously adding lime water into the device while crushing the stone, thereby further realizing the preparation of cement; meanwhile, the crushing effect on stones can be adjusted according to actual conditions, the sliding sleeves 2-18 are slid along the middle-end rotating columns 2-15, the sliding sleeves 2-18 drive the blade hinge rods 2-17 to move, the blade hinge rods 2-17 drive the crushing blades 2-16 to rotate, and the effective contact area of the crushing blades 2-16 and stones is changed through the rotation of the crushing blades 2-16, so that the crushing effect on stones is adjusted; along with the increase of the mass of the cement in the device, the bearing plate 3-2 slides downwards along the lower end sleeve 3-1, the bearing plate 3-2 drives the lower end rotating column 3-5 to move downwards, the lower end bevel gear 3-7 is driven to be in meshed transmission with the lower end bevel gear two 3-8, a matched motor C externally connected with the lower end bevel gear two 3-8 is started, the lower end bevel gear two 3-8 is driven to rotate, the discharging rotating blade 3-9 is driven to rotate through the lower end bevel gear two 3-8, the cement is contacted with the cement through the discharging rotating blade 3-9, the cement flows into the communicating sleeve 3-3 through the rectangular through hole 3-10 and flows out through the communicating sleeve 3-3, thereby realizing the automatic discharge of the cement.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims

1. The utility model provides a building cement mixing apparatus, includes delivery assembly (1), crushing assembly (2), row's material assembly (3), its characterized in that: the carrying assembly (1) is connected with the crushing assembly (2), and the crushing assembly (2) is connected with the discharging assembly (3).

2. The building cement mixing apparatus according to claim 1, wherein: the carrying assembly (1) comprises an upper end sleeve (1-1), an upper end transmission rod (1-2), a carrying belt (1-3), an upper end sliding frame I (1-4), a roller I (1-5), an upper end sliding frame II (1-6), a roller II (1-7), a roller III (1-8), a roller IV (1-9), a roller V (1-10), an upper end clamping groove I (1-11), an upper end clamp I (1-12), an upper end clamp push spring I (1-13), an arc-shaped rod I (1-14), a transmission ball I (1-15), an arc-shaped rod II (1-16), a transmission ball II (1-17), an arc-shaped rod III (1-18) and an arc-shaped rod IV (1-19), wherein the upper end sliding frame I (1-4) is fixedly connected with the upper end sleeve (1-1), the roller I (1-5) is rotatably connected with the upper end sliding frame I (1-4), the roller V (1-10) is rotatably connected with the upper end sliding frame I (1-4), the roller II (1-7), the roller III (1-8) and the roller IV (1-9) are rotatably connected with the upper end sliding frame II (1-6), the upper end sliding frame I (1-4) is slidably connected with the upper end sliding frame II (1-6), the upper end clamping groove I (1-11) is arranged on the end sliding frame II (1-6), the upper end clamp I (1-12) is slidably connected with the upper end sliding frame I (1-4), the upper end clamp I (1-12) is matched and connected with the upper end clamping groove I (1-11), and the upper end clamp push spring I (1-13) is arranged between the upper end clamp I (1-12) and the upper end sliding frame I (1-4), the arc-shaped rods I (1-14) are connected with the transmission balls I (1-15) in a sliding fit mode, the transmission balls I (1-15) are connected with the arc-shaped rods II (1-16) in a sliding fit mode, the arc-shaped rods II (1-16) are fixedly connected with the upper end transmission rod (1-2), the upper end transmission rod (1-2) is fixedly connected with the arc-shaped rods IV (1-19), the arc-shaped rods IV (1-19) are connected with the transmission balls II (1-17) in a sliding fit mode, the transmission balls II (1-17) are connected with the arc-shaped rods III (1-18) in a sliding fit mode, the upper end sliding frames I (1-4) are fixedly connected with the rollers I (1-5), the rollers I (1-5) are provided with a plurality of arc-shaped rods IV (1-19) are fixedly connected with the other rollers I (1-5), and the rollers II (1-7) are externally connected.

3. The building cement mixing apparatus according to claim 1, wherein: the crushing assembly (2) comprises a middle-end sleeve (2-1), a first arc-shaped hinged rod (2-2), a second arc-shaped hinged rod (2-3), a third arc-shaped hinged rod (2-4), a fourth arc-shaped hinged rod (2-5), a fifth arc-shaped hinged rod (2-6), a first middle-end rotating column (2-7), a middle-end fixed support (2-8), an eccentric rotating rod (2-9), a driving rack rod (2-10), a first middle-end pushing spring (2-11), a rectangular middle-end slider (2-12), a limiting rectangular upper-end block (2-13), a second middle-end pushing spring (2-14), a rotating middle-end column (2-15), crushing blades (2-16), blade hinged rods (2-17), sliding sleeves (2-18), a spherical middle-end clamping groove (2-19), A middle-end spherical push spring (2-20), a middle-end spherical clamping rod (2-21), a prismatic clamping rod (2-22) and a prismatic clamping rod push spring (2-23), wherein a middle-end rotating column I (2-7) is rotationally connected with a middle-end sleeve (2-1), an arc-shaped hinge rod I (2-2) is fixedly connected with the middle-end rotating column I (2-7), an arc-shaped hinge rod I (2-2) is rotationally connected with an arc-shaped hinge rod II (2-3), an arc-shaped hinge rod II (2-3) is rotationally connected with an arc-shaped hinge rod III (2-4), an arc-shaped hinge rod III (2-4) is rotationally connected with an arc-shaped hinge rod IV (2-5), an arc-shaped hinge rod IV (2-5) is rotationally connected with an arc-shaped hinge rod V (2-6), and the arc-shaped hinge rod V (2-6) is fixedly connected with other middle-end rotating columns I (2-7), a plurality of middle-end rotating columns I (2-7) are arranged, a middle-end fixing support (2-8) is fixedly connected with a middle-end sleeve (2-1), a middle-end rotating column I (2-7) is rotatably connected with the middle-end fixing support (2-8), an eccentric rotating rod (2-9) is fixedly connected with the middle-end rotating column I (2-7), a driving rack rod (2-10) is slidably connected with the eccentric rotating rod (2-9), a clamping groove A is arranged on the eccentric rotating rod (2-9), a prismatic clamping rod (2-22) is slidably connected with the driving rack rod (2-10), a prismatic clamping rod pushing spring (2-23) is arranged between the prismatic clamping rod (2-22) and the driving rack rod (2-10), the prismatic clamping rod (2-22) is in matched connection with the clamping groove A arranged on the eccentric rotating rod (2-9), the middle-end rectangular sliders (2-12) are connected with the driving rack rods (2-10) in a sliding manner, the middle-end pushing springs (2-11) are connected with the driving rack rods (2-10) in a sleeved manner, the middle-end rectangular sliders (2-12) are arranged between the two middle-end pushing springs (2-11), the upper-end limiting rectangular blocks (2-13) are fixedly connected with the driving rack rods (2-10), the middle-end rectangular sliders (2-12) are connected with the middle-end fixed support (2-8) in a sliding manner, the middle-end pushing springs (2-14) are connected with the middle-end fixed support (2-8) in a sleeved manner, the middle-end pushing springs (2-14) are arranged between the two middle-end rectangular sliders (2-12), the middle-end rotary columns (2-15) are connected with the middle-end fixed support (2-8) in a rotating manner, the driving rack rods (2-10) are meshed with the middle-end rotary columns (2-15) for transmission, the middle-end spherical clamping grooves (2-19) are arranged on the middle-end rotating column (2-15), the crushing blades (2-16) are rotatably connected with the middle-end rotating column (2-15), blade hinged rods (2-17) are hinged with the crushing blades (2-16), the blade hinged rods (2-17) are hinged with sliding sleeves (2-18), middle-end spherical clamping rods (2-21) are slidably connected with the sliding sleeves (2-18), middle-end spherical push springs (2-20) are arranged between the middle-end spherical clamping rods (2-21) and the sliding sleeves (2-18), the middle-end spherical clamping rods (2-21) are connected with the middle-end spherical clamping grooves (2-19) in a matched mode, the middle-end sleeve (2-1) is fixedly connected with the upper-end sleeve (1-1), and a first middle-end rotating column (2-7) is externally connected with a motor B.

4. The building cement mixing apparatus according to claim 1, wherein: the discharging assembly (3) comprises a lower end sleeve (3-1), a bearing plate (3-2), a communicating sleeve (3-3), a lower end cover (3-4), a lower end rotary column (3-5), an inner end spring (3-6), a lower end bevel gear I (3-7), a lower end bevel gear II (3-8), a discharging rotating blade (3-9) and a rectangular through hole (3-10), wherein the bearing plate (3-2) is connected with the lower end sleeve (3-1) in a sliding manner, the communicating sleeve (3-3) is connected with the bearing plate (3-2) in a sliding manner, the communicating sleeve (3-3) is fixedly connected with the lower end sleeve (3-1), the rectangular through hole (3-10) is arranged on the communicating sleeve (3-3), and the lower end cover (3-4) is fixedly connected with the communicating sleeve (3-3), the discharging rotating blades (3-9) are rotatably connected with the lower end cover (3-4), the lower end bevel gear II (3-8) is fixedly connected with the discharging rotating blades (3-9), the lower end rotating column (3-5) is rotatably connected with the bearing plate (3-2), the lower end rotating column (3-5) is slidably connected with the lower end sleeve (3-1), the inner end spring (3-6) is connected with the lower end rotating column (3-5) in a sleeved mode, the inner end spring (3-6) is arranged between the bearing plate (3-2) and the lower end sleeve (3-1), the lower end bevel gear I (3-7) is fixedly connected with the lower end rotating column (3-5), the lower end sleeve (3-1) is fixedly connected with the middle end sleeve (2-1), and the lower end bevel gear II (3-8) is externally connected with a matched motor C.