CN112692997A - Building concrete processing equipment - Google Patents

Abstract

The invention relates to processing equipment, in particular to building concrete processing equipment which comprises a device bracket, a power mechanism, pushing mechanisms, transmission mechanisms, feeding mechanisms, an adjusting mechanism, a water supply mechanism, a swinging mechanism and a stirring mechanism, wherein the power mechanism is fixedly connected to the device bracket, the two pushing mechanisms are fixedly connected to the device bracket, the transmission mechanisms are rotatably connected to the device bracket and are in transmission connection with the power mechanism, the feeding mechanisms are connected to the device bracket, the feeding mechanisms are in transmission connection with the transmission mechanisms through belts, the transmission mechanisms and the water supply mechanism can be driven to move through the power mechanism, under the control of the two pushing mechanisms, the transmission mechanisms and the water supply mechanism provide equal-proportion raw materials for the stirring mechanism in batches, and the raw materials provided by each movement period of the transmission mechanisms and the water supply mechanism are arranged in proportion, the swing mechanism drives the stirring mechanism to swing, and the stirring mechanism rapidly stirs the concrete raw materials in the stirring mechanism.

Description

Building concrete processing equipment

Technical Field

The invention relates to processing equipment, in particular to building concrete processing equipment.

Background

For example, publication No. CN207044404U discloses a mixer for a concrete mixing plant, which solves the problem that the powder and stone materials accumulated at two ends of a mixing tank are easy to be insufficiently mixed, and the quality of concrete is affected. The technical scheme is that the stirrer for the concrete mixing station comprises a mixing tank and a stirring rod penetrating through the mixing tank, wherein two ends of the stirring rod are respectively provided with a scraping helical blade for scraping concrete on the inner wall of the mixing tank, and the two scraping helical blades are respectively a left-handed blade and a right-handed blade; the starting end and the tail end of the scraping helical blade are respectively a scraping end which is tightly attached to the inner wall of the stirring barrel and a material conveying end which extends towards the middle direction of the stirring rod, so that powder and stone accumulated in the two ends of the stirring barrel are pushed to the center of the stirring barrel in the stirring process; the utility model has the disadvantage that different raw materials can not be mixed rapidly and fully according to the proportion.

Disclosure of Invention

The invention aims to provide building concrete processing equipment which can quickly and fully mix different raw materials according to a proportion.

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

a building concrete processing device comprises a device support, power mechanisms, pushing mechanisms, transmission mechanisms, feeding mechanisms, adjusting mechanisms, water supply mechanisms, swinging mechanisms and stirring mechanisms, wherein the power mechanisms are fixedly connected to the device support, the two pushing mechanisms are fixedly connected to the device support, the transmission mechanisms are rotatably connected to the device support and are in transmission connection with the power mechanisms, a plurality of feeding mechanisms are connected to the device support, the plurality of feeding mechanisms are all in transmission connection with the transmission mechanisms through belts, a plurality of adjusting mechanisms are fixedly connected to the device support and are respectively in contact with the transmission belts between the plurality of feeding mechanisms and the transmission mechanisms, the water supply mechanisms are fixedly connected to the device support and are in transmission connection with the power mechanisms, the water supply mechanisms are connected with the stirring mechanisms through pipelines, and the stirring mechanisms are rotatably connected to the swinging mechanisms, the swing mechanism is connected to the device bracket.

As a further optimization of the technical scheme, the building concrete processing equipment comprises two side supports, a connecting plate, a motor support and a rotating support, wherein the connecting plate is fixedly connected between the rear sides of the two side supports, the motor support is fixedly connected between the rear sides of the two side supports, and the rotating support is fixedly connected on the motor support.

As a further optimization of the technical scheme, the building concrete processing equipment comprises a power motor, two power shafts, two power cavities, two sliding cylinders and an inserting column, wherein the power motor is fixedly connected to a motor support, the two power shafts are respectively and rotatably connected to the upper end and the lower end of the rotating support, the two power shafts are in transmission connection with output shafts of the power motor, the power cavities are fixedly connected to the inner sides of the two power shafts, the sliding cylinders are fixedly connected to the two power cavities, the inserting column is slidably connected to the two sliding cylinders, and a compression spring is fixedly connected between the inserting column and the sliding cylinder.

As a further optimization of the technical scheme, the building concrete processing equipment comprises a pushing mechanism, a sliding circular groove, a pushing ring, two pushing circular arc plates and a positioning screw, wherein the sliding circular groove is formed in the pushing ring, the two pushing circular arc plates are connected in the sliding circular groove in a sliding mode and form a pushing part, the two pushing circular arc plates are connected with the positioning screw through threads, the rotating support is fixedly connected with the two pushing rings, the two pushing rings are located on the outer sides of the two power cavities respectively, and the two inserting columns are in contact with the two pushing parts respectively.

As further optimization of the technical scheme, the building concrete processing equipment comprises a transmission mechanism and a plurality of insertion grooves, wherein the transmission mechanism comprises a transmission shaft I, an insertion wheel I, an insertion groove I, a transmission shaft II and a conical friction wheel I, the transmission shaft I is rotatably connected to the upper end of a rotating support, the insertion wheel I is fixedly connected to the transmission shaft I, the insertion wheel I is provided with the insertion grooves I, the transmission shaft II is rotatably connected to a motor support and is in transmission connection with the transmission shaft I, the two ends of the transmission shaft II are fixedly connected with the conical friction wheel I, insertion columns located on the upper side can be inserted into the insertion grooves I, and the insertion wheel I is located in a power cavity on the upper side.

According to the further optimization of the technical scheme, the building concrete processing equipment comprises a feeding mechanism, a feeding pipeline, a discharging pipeline, a feeding shaft, a conical friction wheel II and a feeding baffle, wherein the feeding pipeline is fixedly connected to the feeding cavity, the discharging pipeline is fixedly connected to the lower end of the feeding cavity, the feeding shaft is rotatably connected to the feeding cavity, the conical friction wheel II is fixedly connected to one end of the feeding shaft, the plurality of feeding baffles are fixedly connected to the other end of the feeding shaft, the plurality of feeding baffles are located in the feeding cavity, the interior of the feeding cavity is divided into a plurality of feeding spaces by the plurality of feeding baffles, the feeding cavity is fixedly connected to the inner sides of two side brackets, the two conical friction wheels II are respectively connected with the two conical friction wheels I through belt transmission, and the conical degrees of the conical friction wheels II and the conical friction wheels I are equal.

As a further optimization of the technical scheme, the adjusting mechanism comprises a telescopic mechanism and limiting baffles, the telescopic end of the telescopic mechanism is fixedly connected with the limiting baffles, the two side brackets are both fixedly connected with the telescopic mechanism, and the two limiting baffles are respectively contacted with the two conical friction wheels ii and the transmission belt between the two conical friction wheels i.

As further optimization of the technical scheme, the building concrete processing equipment comprises a water supply mechanism, an inserting wheel II, inserting grooves II, a water supply pump, a driving shaft, a water inlet pipeline and a water outlet pipeline, wherein the water supply mechanism comprises a water supply shaft, the inserting wheel II, inserting grooves II, a water supply pump, a driving shaft, a water inlet pipeline and a water outlet pipeline, the water supply shaft is rotatably connected to a rotating support, the inserting wheel II is fixedly connected to the water supply shaft, a plurality of inserting grooves II are formed in the inserting wheel II, the inserting wheel II is located in a power cavity on the lower side, a sliding cylinder on the lower side can be inserted into the inserting grooves II, the water supply pump is fixedly connected to a connecting plate, the driving.

As a further optimization of the technical scheme, the building concrete processing equipment comprises a swing mechanism, a swing support, a swing ring and a swing shaft, wherein the swing shaft is connected between the two side supports in a transmission manner, the swing support is fixedly connected to the swing shaft, the swing ring is fixedly connected to the swing shaft, and the swing shaft is in transmission connection with an output shaft of the swing motor.

As a further optimization of the technical scheme, the building concrete processing equipment comprises a stirring mechanism, a stirring screw I, water inlet holes, a water inlet cavity, a connecting pipeline, a stirring motor, a gear ring and a stirring screw II, wherein the stirring screw I is fixedly connected in the stirring cavity, the stirring cavity is rotatably connected to a swinging ring, a plurality of water inlet holes are formed in the stirring cavity, the water inlet cavity is rotatably connected to the stirring cavity and is communicated with the water inlet holes, the connecting pipeline is arranged on the water inlet cavity and is connected with a water outlet pipeline through a pipeline, the stirring motor is fixedly connected to a swinging bracket, the gear is rotatably connected to the swinging bracket, the gear is in meshing transmission with an output shaft of the stirring motor, the gear ring is fixedly connected to the lower end of the stirring cavity and is in meshing transmission with the gear ring, the stirring screw II is fixedly connected to an output shaft of the stirring motor, stirring spiral II is located the stirring cavity, and the spiral of stirring spiral II and stirring spiral I is to the same.

The building concrete processing equipment has the beneficial effects that:

the building concrete processing equipment can drive the transmission mechanism and the water supply mechanism to move through the power mechanism, under the control of the two pushing mechanisms, the transmission mechanism and the water supply mechanism provide equal-proportion raw materials for the stirring mechanism in batches, the raw materials provided by the transmission mechanism and the water supply mechanism in each movement period are arranged in proportion, the swinging mechanism drives the stirring mechanism to swing, and the stirring mechanism rapidly stirs the concrete raw materials in the stirring mechanism.

Drawings

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

FIG. 1 is a schematic view showing the overall construction of the construction concrete processing apparatus of the present invention;

FIG. 2 is a schematic view of the device support structure of the present invention;

FIG. 3 is a schematic diagram of a power mechanism according to the present invention;

FIG. 4 is a schematic view of the pushing mechanism of the present invention;

FIG. 5 is a schematic view of the transmission mechanism of the present invention;

FIG. 6 is a first schematic structural diagram of the feeding mechanism of the present invention;

FIG. 7 is a second schematic structural view of the feeding mechanism of the present invention;

FIG. 8 is a schematic view of the adjustment mechanism of the present invention;

FIG. 9 is a schematic view of the water supply mechanism of the present invention;

FIG. 10 is a schematic view of the swing mechanism of the present invention;

FIG. 11 is a schematic view of the stirring mechanism of the present invention;

fig. 12 is a schematic structural view of a cross section of the stirring mechanism of the present invention.

In the figure: a device holder 1; side brackets 101; a connecting plate 102; a motor bracket 103; a rotating bracket 104; a power mechanism 2; a power motor 201; a power shaft 202; a power cavity 203; a slide cylinder 204; a plug-in column 205; a pushing mechanism 3; a sliding circular groove 301; a push ring 302; pushing the arc plate 303; a set screw 304; a transmission mechanism 4; a transmission shaft I401; an insertion wheel I402; slot I403; a transmission shaft II 404; a conical friction wheel I405; a feeding mechanism 5; a feed chamber 501; a feed conduit 502; a discharge conduit 503; a supply shaft 504; a conical friction wheel II 505; a feed baffle 506; an adjusting mechanism 6; a telescoping mechanism 601; a limit stop 602; a water supply mechanism 7; a water supply shaft 701; an insertion wheel II 702; a slot II 703; a water supply pump 704; a drive shaft 705; an inlet conduit 706; an outlet conduit 707; a swing mechanism 8; a swing motor 801; a swing frame 802; a swinging ring 803; a swing shaft 804; a stirring mechanism 9; a stirring chamber 901; a stirring screw I902; an inlet hole 903; a water inlet cavity 904; a connecting pipe 905; a stirring motor 906; a gear 907; ring gear 908; stirring screw II 909.

Detailed Description

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

In the description of the present invention, it should be noted that the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "top", "bottom", "inner", "outer" and "upright", etc., indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that unless otherwise explicitly stated or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected, directly or indirectly connected through an intermediate medium, and may be a communication between two members. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In addition, in the description of the present invention, the meaning of "a plurality", and "a plurality" is two or more unless otherwise specified.

The first embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 12, and a building concrete processing apparatus includes a device support 1, a power mechanism 2, pushing mechanisms 3, a transmission mechanism 4, a feeding mechanism 5, adjusting mechanisms 6, a water supply mechanism 7, a swinging mechanism 8 and a stirring mechanism 9, wherein the power mechanism 2 is fixedly connected to the device support 1, the two pushing mechanisms 3 are fixedly connected to the device support 1, the transmission mechanism 4 is rotatably connected to the device support 1, the transmission mechanism 4 is in transmission connection with the power mechanism 2, a plurality of feeding mechanisms 5 are connected to the device support 1, the plurality of feeding mechanisms 5 are all in transmission connection with the transmission mechanism 4 through a belt, the plurality of adjusting mechanisms 6 are fixedly connected to the device support 1, the plurality of adjusting mechanisms 6 are respectively in contact with transmission belts between the plurality of feeding mechanisms 5 and the transmission mechanisms 4, the water supply mechanism 7 is fixedly connected to the device support 1, the water supply mechanism 7 is in transmission connection with the power mechanism 2, the water supply mechanism 7 is connected with the stirring mechanism 9 through a pipeline, the stirring mechanism 9 is rotationally connected to the swinging mechanism 8, and the swinging mechanism 8 is connected to the device bracket 1; can drive mechanism 4 and water supply mechanism 7 through power unit 2 and move, under the control of two pushing mechanism 3, drive mechanism 4 and water supply mechanism 7 will provide equal proportion's raw materials to rabbling mechanism 9 in batches, and the raw materials that every movement cycle of drive mechanism 4 and water supply mechanism 7 provided all sets up in proportion, and swing mechanism 8 drives rabbling mechanism 9 and swings, and rabbling mechanism 9 carries out rapid mixing to the concrete raw materials in it.

The second embodiment is as follows:

the present embodiment is described below with reference to fig. 1 to 12, and the present embodiment further describes the first embodiment, where the apparatus bracket 1 includes two side brackets 101, two connecting plates 102, two motor brackets 103, and a rotating bracket 104, the connecting plates 102 are fixedly connected between the rear sides of the two side brackets 101, the motor brackets 103 are fixedly connected between the rear sides of the two side brackets 101, and the rotating bracket 104 is fixedly connected to the motor brackets 103.

The third concrete implementation mode:

the following describes the present embodiment with reference to fig. 1 to 12, and the present embodiment further describes an embodiment two, where the power mechanism 2 includes a power motor 201, power shafts 202, power cavities 203, sliding cylinders 204, and insertion columns 205, the power motor 201 is fixedly connected to the motor support 103, the power shafts 202 are provided with two numbers, the two power shafts 202 are respectively rotatably connected to the upper and lower ends of the rotating support 104, the two power shafts 202 are both in transmission connection with output shafts of the power motor 201, the power cavities 203 are both fixedly connected to the inner sides of the two power shafts 202, the sliding cylinders 204 are both fixedly connected to the two power cavities 203, the insertion columns 205 are both slidably connected to the two sliding cylinders 204, and compression springs are fixedly connected between the insertion columns 205 and the sliding cylinders 204.

The fourth concrete implementation mode:

this embodiment is described below with reference to fig. 1 to 12, and this embodiment further describes the third embodiment, pushing mechanism 3 includes sliding circular groove 301, push ring 302, push circular arc plate 303 and set screw 304, be provided with sliding circular groove 301 on the push ring 302, sliding connection has two to push circular arc plate 303 in the sliding circular groove 301, two push circular arc plates 303 constitute the pushing component, all there is set screw 304 through threaded connection on two push circular arc plates 303, two push rings 302 of fixedly connected with on the rotating bracket 104, two push rings 302 are located the outside of two power cavities 203 respectively, two insert posts 205 contact with two pushing components respectively.

The fifth concrete implementation mode:

the fourth embodiment is further described with reference to fig. 1 to 12, where the transmission mechanism 4 includes a transmission shaft i 401, an insertion wheel i 402, an insertion slot i 403, a transmission shaft ii 404 and a tapered friction wheel i 405, the transmission shaft i 401 is rotatably connected to the upper end of the rotating bracket 104, the transmission shaft i 401 is fixedly connected to the insertion wheel i 402, the insertion wheel i 402 is provided with a plurality of insertion slots i 403, the transmission shaft ii 404 is rotatably connected to the motor bracket 103, the transmission shaft ii 404 is in transmission connection with the transmission shaft i 401, both ends of the transmission shaft ii 404 are fixedly connected to the tapered friction wheel i 405, the insertion column 205 located on the upper side can be inserted into the insertion slot i, and the insertion wheel i 402 is located in the power cavity 203 on the upper side.

The sixth specific implementation mode:

the present embodiment is described below with reference to fig. 1 to 12, and the present embodiment further describes the fifth embodiment, the feeding mechanism 5 includes a feeding cavity 501, a feeding pipe 502, a discharging pipe 503, a feeding shaft 504, a tapered friction wheel ii 505 and a feeding baffle 506, the feeding pipe 502 is fixedly connected to the feeding cavity 501, the discharging pipe 503 is fixedly connected to the lower end of the feeding cavity 501, the feeding shaft 504 is rotatably connected to the feeding cavity 501, the tapered friction wheel ii 505 is fixedly connected to one end of the feeding shaft 504, a plurality of feeding baffles 506 are fixedly connected to the other end of the feeding shaft 504, the plurality of feeding baffles 506 are all located in the feeding cavity 501, the plurality of feeding baffles 506 divide the inside of the feeding cavity 501 into a plurality of feeding spaces, the feeding cavities 501 are fixedly connected to the inner sides of the two side brackets 101, the two tapered friction wheels ii 505 are respectively connected to the two tapered friction wheels i 405 through belt transmission, the conical degrees of the conical friction wheel II 505 and the conical friction wheel I405 are equal; the number of the feeding mechanisms 5 can be multiple according to the use requirement, the number of the corresponding parts connected with the feeding mechanisms 5 is multiple, as shown in fig. 1, two feeding mechanisms 5 are provided, two conical friction wheels i 405 are provided, two adjusting mechanisms 6 are provided, concrete raw materials generally comprise yellow sand, cement and stone, preferably, three feeding mechanisms 5 are provided, three corresponding conical friction wheels i 405 are provided, and three adjusting mechanisms 6 are provided, and the arrangement can be performed by a person skilled in the art according to the use requirement; the transmission ratio of the conical friction wheel I405 and the conical friction wheel II 505 is adjusted in advance according to the connecting position of the pipeline of the raw materials, for example, the ratio of cement to yellow sand to stone is 1: 4: 7, the transmission ratio between the feeding mechanism 5 connected with cement and the conical friction wheel I405 is one, the conical friction wheel II 505 rotates for one circle when the conical friction wheel I405 rotates for one circle, the transmission ratio between the feeding mechanism 5 connected with yellow sand and the conical friction wheel I405 is one fourth, the conical friction wheel II 505 rotates for four circles when the conical friction wheel I405 rotates for one circle, the transmission ratio between the feeding mechanism 5 connected with stone bits and the conical friction wheel I405 is one seventh, the conical friction wheel II 505 rotates for seven circles when the conical friction wheel I405 rotates for one circle, and raw materials with equal proportion are supplied to the stirring mechanism 9; after the post 205 of inserting that is located the upside inserts in slot I403, it drives and inserts I402 of taking turns and rotate to insert the post 205, it drives transmission shaft I401 and rotates to insert I402 of taking turns, transmission shaft I401 drives transmission shaft II 404 and rotates, transmission shaft II 404 drives I405 of toper friction pulley and rotates, I405 of toper friction pulley drives II 505 of toper friction pulley and rotates, II 505 of toper friction pulley drive feeding axle 504 rotate, feeding axle 504 drives a plurality of feed baffles 506 and rotates, a plurality of feed spaces are cut apart into with the inside of feed cavity 501 to a plurality of feed baffles 506, a plurality of feed baffles 506 will correspond the raw materials when rotating and bring into out the pipeline 503 from pan feeding pipeline 502 in, and then fall in stirring cavity 901.

The seventh embodiment:

the embodiment is described below with reference to fig. 1 to 12, and the sixth embodiment is further described in the present embodiment, where the adjusting mechanism 6 includes a telescopic mechanism 601 and a limit baffle 602, a telescopic end of the telescopic mechanism 601 is fixedly connected with the limit baffle 602, the telescopic mechanisms 601 are fixedly connected to both side brackets 101, and the two limit baffles 602 are respectively in contact with the transmission belts between the two conical friction wheels ii 505 and the two conical friction wheels i 405; the telescopic mechanism 601 is started, the telescopic mechanism 601 can be a hydraulic cylinder or an electric push rod, the telescopic end of the telescopic mechanism 601 drives the limit baffle 602 to move, the limit baffle 602 drives a transmission belt between the corresponding conical friction wheel I405 and the conical friction wheel II 505 to move, and then the transmission ratio between the corresponding conical friction wheel I405 and the conical friction wheel II 505 is adjusted.

The specific implementation mode is eight:

the present embodiment is described below with reference to fig. 1 to 12, and the seventh embodiment is further described in the present embodiment, where the water supply mechanism 7 includes a water supply shaft 701, an insertion wheel ii 702, an insertion groove ii 703, a water supply pump 704, a driving shaft 705, a water inlet pipe 706, and a water outlet pipe 707, the water supply shaft 701 is rotatably connected to the rotating bracket 104, the insertion wheel ii 702 is fixedly connected to the water supply shaft 701, the insertion wheel ii 702 is provided with a plurality of insertion grooves ii 703, the insertion wheel ii 702 is located in the lower power cavity 203, the sliding cylinder 204 located on the lower side can be inserted into the insertion groove ii 703, the water supply pump 704 is fixedly connected to the connecting plate 102, the driving shaft 705 of the water supply pump 704 is in transmission connection with the water supply shaft 701, and the water supply pump 704 is; when the lower inserting column 205 is inserted into the inserting groove II 703, the inserting column 205 drives the inserting wheel II 702 to rotate, the inserting wheel II 702 drives the water supply shaft 701 to rotate, the water supply shaft 701 drives the driving shaft 705 to rotate, the driving shaft 705 is a driving shaft of the water supply pump 704, the driving shaft 705 drives the water supply pump 704 to move when rotating, the water supply pipeline is connected with the water inlet pipeline 706 in advance, the water supply pump 704 pumps water in the water inlet pipeline 706 into the water outlet pipeline 707, the water outlet pipeline 707 is connected with the connecting pipeline 905 through a pipeline, the pipeline between the water outlet pipeline 707 and the connecting pipeline 905 is not as short as that shown in fig. 1, but is a long hose, the connecting pipeline 905 leads the water into the water inlet cavity 904, the water flows into the stirring cavity 901 through the plurality of water inlet holes 903, and the water is uniformly led into the stirring cavity 901, so that the water and the concrete are uniformly contacted in all.

The specific implementation method nine:

the present embodiment is described below with reference to fig. 1 to 12, and the eighth embodiment is further described in the present embodiment, where the swing mechanism 8 includes a swing motor 801, a swing bracket 802, a swing ring 803, and a swing shaft 804, the swing shaft 804 is connected between the two side brackets 101 in a transmission manner, the swing bracket 802 is fixedly connected to the swing shaft 804, the swing ring 803 is fixedly connected to the swing shaft 804, and the swing shaft 804 is connected to an output shaft of the swing motor 801 in a transmission manner.

The detailed implementation mode is ten:

the present embodiment is described below with reference to fig. 1 to 12, and the present embodiment further describes an embodiment nine, where the stirring mechanism 9 includes a stirring cavity 901, a stirring helix i 902, a water inlet 903, a water inlet cavity 904, a connecting pipe 905, a stirring motor 906, a gear 907, a gear ring 908, and a stirring helix ii 909, the stirring cavity 901 is fixedly connected with the stirring helix i 902, the stirring cavity 901 is rotatably connected to the swinging ring 803, the stirring cavity 901 is provided with a plurality of water inlet holes 903, the stirring cavity 901 is rotatably connected with the water inlet cavity 904, the water inlet cavity 904 is communicated with the plurality of water inlet holes 903, the water inlet cavity 904 is provided with the connecting pipe 905, the connecting pipe 905 and the water outlet pipe 707 are connected through a pipe, the stirring motor 906 is fixedly connected to the swinging bracket 802, the gear 907 is rotatably connected to the swinging bracket 802, the gear 907 is engaged with an output shaft of the stirring motor 906, the lower end of the stirring cavity 901 is fixedly connected with a gear ring 908, the gear ring 908 is in meshing transmission with a gear 907, an output shaft of the stirring motor 906 is fixedly connected with a stirring screw II 909, the stirring screw II 909 is positioned in the stirring cavity 901, and the spiral directions of the stirring screw II 909 and the stirring screw I902 are the same.

The invention relates to a building concrete processing device, which has the working principle that:

when the concrete feeding device is used, pipelines of concrete raw materials are respectively connected to the feeding pipeline 502, a plurality of feeding mechanisms 5 can be arranged according to use requirements, and a plurality of corresponding parts connected with the feeding mechanisms 5 are also arranged, as shown in fig. 1, two feeding mechanisms 5 are arranged, two conical friction wheels I405 are arranged, two adjusting mechanisms 6 are arranged, the concrete raw materials are generally yellow sand, cement and stone, preferably, three feeding mechanisms 5 are arranged, three corresponding conical friction wheels I405 are arranged, three adjusting mechanisms 6 are arranged, and the concrete feeding device can be arranged by a person skilled in the art according to use requirements; the transmission ratio of the conical friction wheel I405 and the conical friction wheel II 505 is adjusted in advance according to the connecting position of the pipeline of the raw materials, for example, the ratio of cement to yellow sand to stone is 1: 4: 7, the transmission ratio between the feeding mechanism 5 connected with cement and the conical friction wheel I405 is one, the conical friction wheel II 505 rotates for one circle when the conical friction wheel I405 rotates for one circle, the transmission ratio between the yellow sand feeding mechanism 5 connected with the yellow sand feeding mechanism and the conical friction wheel I405 is one fourth, the conical friction wheel II 505 rotates for four circles when the conical friction wheel I405 rotates for one circle, the transmission ratio between the stone head feeding mechanism 5 connected with the stone head feeding mechanism and the conical friction wheel I405 is one seventh, the conical friction wheel II 505 rotates for seven circles when the conical friction wheel I405 rotates for one circle, raw materials with equal proportion are supplied into the stirring mechanism 9, the telescopic mechanism 601 is started, the telescopic mechanism 601 can be a hydraulic cylinder or an electric push rod, the telescopic end of the telescopic mechanism 601 drives the limit baffle 602 to move, the limit baffle 602 drives the transmission belt between the corresponding conical friction wheel I405 and the conical friction wheel II 505 to move, further adjusting the transmission ratio between the corresponding conical friction wheel I405 and the conical friction wheel II 505; after the device is adjusted, the power mechanism 2 is started, an output shaft of the power mechanism 2 drives the two power shafts 202 to rotate, the two power shafts 202 respectively drive the two power cavities 203 to rotate, the two power cavities 203 respectively drive the two sliding cylinders 204 to rotate, the two sliding cylinders 204 respectively drive the two inserting columns 205 to move, the sliding circular groove 301 is connected with the two pushing circular arc plates 303 in a sliding manner, the two pushing circular arc plates 303 form a pushing part, the two inserting columns 205 are in contact with the pushing part in the rotating process, the pushing part pushes the corresponding inserting columns 205 to move inwards, the inserting columns 205 are inserted into the corresponding inserting grooves I403 or II 703, the pushing period of the pushing part can be adjusted according to the use requirement, the staggered distance between the two pushing circular arc plates 303 is adjusted, the path for the pushing part to push the inserting columns 205 to move can be adjusted, and the moving time of the transmission mechanism 4 and the water supply mechanism 7 is further controlled, the mixing proportion between the concrete raw materials and the water is further controlled, the position of the pushing component in the sliding circular groove 301 is adjusted, the movement time interval of the transmission mechanism 4 and the water supply mechanism 7 can be adjusted, namely, feeding and water supply are carried out together, feeding and water supply are carried out respectively, or feeding and water supply are carried out in a staggered mode, and the adjustment can be carried out according to the use requirement; after the inserting column 205 positioned on the upper side is inserted into the slot I403, the inserting column 205 drives the inserting wheel I402 to rotate, the inserting wheel I402 drives the transmission shaft I401 to rotate, the transmission shaft I401 drives the transmission shaft II 404 to rotate, the transmission shaft II 404 drives the conical friction wheel I405 to rotate, the conical friction wheel I405 drives the conical friction wheel II 505 to rotate, the conical friction wheel II 505 drives the feeding shaft 504 to rotate, the feeding shaft 504 drives the plurality of feeding baffles 506 to rotate, the plurality of feeding baffles 506 divide the interior of the feeding cavity 501 into a plurality of feeding spaces, and the plurality of feeding baffles 506 bring corresponding raw materials into the discharging pipeline 503 from the feeding pipeline 502 when rotating, and then fall into the stirring cavity 901; when the lower inserting column 205 is inserted into the inserting groove II 703, the inserting column 205 drives the inserting wheel II 702 to rotate, the inserting wheel II 702 drives the water supply shaft 701 to rotate, the water supply shaft 701 drives the driving shaft 705 to rotate, the driving shaft 705 is a driving shaft of the water supply pump 704, the driving shaft 705 drives the water supply pump 704 to move when rotating, the water supply pipeline is connected with the water inlet pipeline 706 in advance, the water supply pump 704 pumps water in the water inlet pipeline 706 into the water outlet pipeline 707, the water outlet pipeline 707 is connected with the connecting pipeline 905 through a pipeline, the pipeline between the water outlet pipeline 707 and the connecting pipeline 905 is not as short as that shown in FIG. 1, but is a long hose, the connecting pipeline 905 leads water into the water inlet cavity 904, the water flows into the stirring cavity 901 through a plurality of water inlet holes 903, and the water is uniformly led into the stirring cavity 901, so that the water and the concrete are uniformly contacted in all directions; when stirring, the stirring motor 906 is started, the output shaft of the stirring motor 906 drives the gear 907 to rotate, the gear 907 drives the gear ring 908 to rotate, the gear ring 908 drives the stirring cavity 901 to rotate, the stirring cavity 901 drives the stirring screw I902 to rotate, the output shaft of the stirring motor 906 drives the stirring screw II 909 to rotate, the rotation directions of the stirring screw I902 and the stirring screw II 909 are opposite, the rotation directions of the stirring screw II 909 and the stirring screw I902 are the same, an upward or downward component force is generated when the stirring screw I902 rotates, an upward or downward component force is generated when the stirring screw II 909 rotates, for example, an upward component force is generated when the stirring screw I902 rotates, a downward component force is generated when the stirring screw II 909 rotates, the stirring screw I902 and the stirring screw II 909 rotate in a matched mode, raw materials and water in the side support 101 are stirred, and simultaneously the stirring screw I and the stirring screw II 909 generate a cycle of pushing the raw materials and the water up and, so that the raw materials and the water are quickly mixed; the swing motor 801 is started, an output shaft of the swing motor 801 drives the swing support 802 to swing, the swing support 802 drives the swing circular ring 803 to swing, and the swing circular ring 803 drives the stirring mechanism 9 to swing, so that the stirring effect is further improved.

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 (10)

1. The utility model provides a building concrete processing equipment, includes device support (1), power unit (2), pushing mechanism (3), drive mechanism (4), feed mechanism (5), guiding mechanism (6), water supply mechanism (7), swing mechanism (8) and rabbling mechanism (9), its characterized in that: the device is characterized in that a power mechanism (2) is fixedly connected to a device support (1), two pushing mechanisms (3) are fixedly connected to the device support (1), a transmission mechanism (4) is rotatably connected to the device support (1), the transmission mechanism (4) is in transmission connection with the power mechanism (2), a plurality of feeding mechanisms (5) are connected to the device support (1), the plurality of feeding mechanisms (5) are in transmission connection with the transmission mechanism (4) through belts, a plurality of adjusting mechanisms (6) are fixedly connected to the device support (1), the plurality of adjusting mechanisms (6) are in contact with transmission belts between the plurality of feeding mechanisms (5) and the transmission mechanism (4) respectively, a water supply mechanism (7) is fixedly connected to the device support (1), the water supply mechanism (7) is in transmission connection with the power mechanism (2), the water supply mechanism (7) is in pipeline connection with a stirring mechanism (9), the stirring mechanism (9) is rotationally connected to the swinging mechanism (8), and the swinging mechanism (8) is connected to the device bracket (1).

2. The building concrete processing apparatus of claim 1, wherein: the device support (1) comprises side supports (101), connecting plates (102), motor supports (103) and rotating supports (104), the number of the side supports (101) is two, the connecting plates (102) are fixedly connected between the rear sides of the two side supports (101), the motor supports (103) are fixedly connected between the rear sides of the two side supports (101), and the rotating supports (104) are fixedly connected to the motor supports (103).

3. The building concrete processing apparatus of claim 2, wherein: the power mechanism (2) comprises a power motor (201), power shafts (202), power cavities (203), sliding cylinders (204) and inserting columns (205), the power motor (201) is fixedly connected to a motor support (103), the number of the power shafts (202) is two, the two power shafts (202) are respectively connected to the upper end and the lower end of a rotating support (104) in a rotating mode, the two power shafts (202) are connected with an output shaft of the power motor (201) in a transmission mode, the power cavities (203) are fixedly connected to the inner sides of the two power shafts (202), the sliding cylinders (204) are fixedly connected to the two power cavities (203), the inserting columns (205) are connected to the two sliding cylinders (204) in a sliding mode, and compression springs are fixedly connected between the inserting columns (205) and the sliding cylinders (204).

4. The building concrete processing apparatus of claim 3, wherein: pushing mechanism (3) are including slip circular slot (301), promote ring (302), promote circular arc board (303) and set screw (304), be provided with slip circular slot (301) on promotion ring (302), sliding connection has two promotion circular arc boards (303) in slip circular slot (301), two promotion circular arc boards (303) are constituteed and are promoted the part, it has set screw (304) all to promote on circular arc board (303) through threaded connection, rotate support (104) and go up two fixedly connected with and promote ring (302), two are promoted the outside that ring (302) are located two power cavity (203) respectively, two are inserted post (205) and are promoted the part contact with two respectively.

5. The building concrete processing apparatus of claim 4, wherein: drive mechanism (4) are including transmission shaft I (401), insert wheel I (402), slot I (403), transmission shaft II (404) and toper friction pulley I (405), transmission shaft I (401) are rotated and are connected the upper end of rotating support (104), fixedly connected with inserts wheel I (402) on transmission shaft I (401), it is provided with a plurality of slots I (403) on wheel I (402) to insert, on transmission shaft II (404) are rotated and are connected motor support (103), transmission shaft II (404) and transmission shaft I (401) transmission are connected, the equal fixedly connected with toper friction pulley I (405) in both ends of transmission shaft II (404), it can insert slot I (403) to be located post (205) of inserting of upside, it is located power cavity (203) of upside to insert wheel I (402).

6. The building concrete processing apparatus of claim 5, wherein: the feeding mechanism (5) comprises a feeding cavity (501), a feeding pipeline (502), a discharging pipeline (503), a feeding shaft (504), a conical friction wheel II (505) and feeding baffles (506), the feeding pipeline (502) is fixedly connected to the feeding cavity (501), the discharging pipeline (503) is fixedly connected to the lower end of the feeding cavity (501), the feeding shaft (504) is rotatably connected to the feeding cavity (501), the conical friction wheel II (505) is fixedly connected to one end of the feeding shaft (504), a plurality of feeding baffles (506) are fixedly connected to the other end of the feeding shaft (504), the plurality of feeding baffles (506) are all located in the feeding cavity (501), the feeding cavities (501) are divided into a plurality of feeding spaces by the plurality of feeding baffles (506), the feeding cavities (501) are fixedly connected to the inner sides of the two side supports (101), the two conical friction wheels II (505) are respectively connected with the two conical friction wheels I (405) through belt transmission, the conical degree of the conical friction wheel II (505) is equal to that of the conical friction wheel I (405).

7. The building concrete processing apparatus of claim 6, wherein: the adjusting mechanism (6) comprises a telescopic mechanism (601) and a limit baffle (602), the telescopic end of the telescopic mechanism (601) is fixedly connected with the limit baffle (602), the two side brackets (101) are fixedly connected with the telescopic mechanism (601), and the two limit baffles (602) are respectively contacted with two conical friction wheels II (505) and a transmission belt between the two conical friction wheels I (405).

8. The building concrete processing apparatus of claim 7, wherein: the water supply mechanism (7) comprises a water supply shaft (701), an inserting wheel II (702), inserting grooves II (703), a water supply pump (704), a driving shaft (705), a water inlet pipeline (706) and a water outlet pipeline (707), the water supply shaft (701) is rotatably connected to the rotating support (104), the inserting wheel II (702) is fixedly connected to the water supply shaft (701), a plurality of inserting grooves II (703) are arranged on the inserting wheel II (702), the inserting wheel II (702) is located in the power cavity (203) on the lower side, a sliding cylinder (204) on the lower side can be inserted into the inserting grooves II (703), the water supply pump (704) is fixedly connected to the connecting plate (102), the driving shaft (705) of the water supply pump (704) is in transmission connection with the water supply shaft (701), and the water supply pump (704) is provided with the water inlet pipeline (706) and the water outlet pipeline (707.

9. The building concrete processing apparatus of claim 8, wherein: the swing mechanism (8) comprises a swing motor (801), a swing support (802), a swing ring (803) and a swing shaft (804), the swing shaft (804) is connected between the two side supports (101) in a transmission mode, the swing support (802) is fixedly connected to the swing shaft (804), the swing ring (803) is fixedly connected to the swing shaft (804), and the swing shaft (804) is in transmission connection with an output shaft of the swing motor (801).

10. The building concrete processing apparatus of claim 9, wherein: the stirring mechanism (9) comprises a stirring cavity (901), a stirring spiral I (902), water inlet holes (903), a water inlet cavity (904), a connecting pipeline (905), a stirring motor (906), a gear (907), a gear ring (908) and a stirring spiral II (909), wherein the stirring cavity (901) is internally and fixedly connected with the stirring spiral I (902), the stirring cavity (901) is rotatably connected onto the swinging ring (803), the stirring cavity (901) is provided with a plurality of water inlet holes (903), the stirring cavity (901) is rotatably connected with the water inlet cavity (904), the water inlet cavity (904) is communicated with the plurality of water inlet holes (903), the water inlet cavity (904) is provided with a connecting pipeline (905), the connecting pipeline (905) is connected with a water outlet pipeline (707) through a pipeline, the stirring motor (906) is fixedly connected onto the swinging bracket (802), the gear (907) is rotatably connected onto the swinging bracket (802), the gear (907) is in meshing transmission with an output shaft of the stirring motor (906), a gear ring (908) is fixedly connected to the lower end of the stirring cavity (901), the gear ring (908) is in meshing transmission with the gear (907), a stirring spiral II (909) is fixedly connected to the output shaft of the stirring motor (906), the stirring spiral II (909) is located in the stirring cavity (901), and spiral directions of the stirring spiral II (909) and the stirring spiral I (902) are the same.

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