CN212077938U - A concrete placement pressure device for water conservancy construction - Google Patents

Abstract

The utility model relates to a concrete placement technical field especially relates to a concrete placement pressure device for water conservancy construction, including pouring the support frame, distance adjusting mechanism, feeding loading system and vibrating rod placer, it includes the support frame, sliding sleeve and mounting groove to pour the support frame, distance adjusting mechanism includes adjustment motor, left sliding sleeve, right sliding sleeve, sliding support board, initiative bevel gear, transmission bevel gear, dwang A, adjustment threaded rod and adjusting gear, feeding loading system is including connecing the feed bin, including a motor, an end cap, a discharge head, drive gear, dwang B and helical blade, vibrating rod placer includes fixed slide rail, lifting block, fixed cover, lifting motor and threaded rod, the utility model discloses be provided with the fixed cover of vibrating rod and can make the vibrating rod vertical all the time, can make the concrete pour the result better.

Description

A concrete placement pressure device for water conservancy construction

Technical Field

The utility model relates to a concrete placement technical field especially relates to a concrete placement pressure device for water conservancy construction.

Background

The concrete pouring refers to the process from pouring concrete into a mold to plasticizing, and under the condition of hot weather, the temperature of the concrete when the concrete is poured into the mold should not exceed 30 ℃, the direct irradiation of the template and the newly poured concrete by sunlight should be avoided, and the temperature of the template and the reinforcing steel bar before the concrete is poured into the mold and the nearby local air temperature are controlled not to exceed 40 ℃. The method is preferably arranged to start pouring in the evening, pouring is not performed in the morning so as to avoid aggravating the internal temperature rise of the concrete when the air temperature rises to the maximum, the temperature difference between the cast-in temperature of the newly-poured concrete and the adjacent hardened concrete or rock-soil, reinforcing steel bars and template media is not more than 15 ℃, the temperature of the hardened concrete, the rock-soil media, the reinforcing steel bars and the template which are in contact with the newly-poured concrete is not less than 2 ℃, measures such as field sprinkling, spraying and wind shielding can be adopted under the environmental conditions of small relative humidity and large wind speed, or a member with a large exposed area is prevented from being poured at the moment, the concrete pouring is continuously performed, the phenomenon of insufficient or excessive vibration can occur in the concrete pouring process, and the phenomenon that a vibrating rod moves obliquely in the concrete can occur to influence the concrete pouring result.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a concrete placement pressure device for water conservancy construction is provided with the fixed cover of vibrating rod and can makes the vibrating rod vertical all the time, can make the concrete pour the result better.

The purpose of the utility model is realized through the following technical scheme:

a concrete pouring pressurizing device for water conservancy construction comprises pouring support frames, a distance adjusting mechanism, two feeding pressurizing mechanisms and a vibrating rod placing mechanism, wherein the two pouring support frames are fixedly connected to two ends of the distance adjusting mechanism respectively;

the pouring support frame comprises a support frame, a sliding sleeve and an installation groove, the sliding sleeve is fixedly connected to the support frame, and the installation groove is formed in the support frame;

the distance adjusting mechanism comprises an adjusting motor, a left sliding sleeve, a right sliding sleeve, a sliding support plate, a driving bevel gear, a transmission bevel gear, a rotating rod A, an adjusting threaded rod and an adjusting gear, wherein the left sliding sleeve and the right sliding sleeve are respectively and fixedly connected to the two support frames, the sliding support plate is slidably connected in the left sliding sleeve and the right sliding sleeve, the driving bevel gear is fixedly connected to the left sliding sleeve, the driving bevel gear is fixedly connected to an output shaft of the adjusting motor, the driving bevel gear is in meshing transmission with the transmission bevel gear at the upper end, the two transmission bevel gears are respectively and fixedly connected to the two ends of the rotating rod A, the rotating rod A is rotatably connected in the sliding support plate, the transmission bevel gear at the lower end is in meshing transmission with the adjusting gear, the adjusting gear is fixedly connected to the adjusting threaded rod, the, the rotating rod A is rotatably connected in the mounting groove;

the feeding pressurization mechanism comprises a material receiving bin, a motor, connecting sleeves, material discharging heads, a transmission gear, rotating rods B and helical blades, wherein the motor is fixedly connected to the upper end of the material receiving bin;

the vibrating rod placing mechanism comprises a fixed slide rail, a lifting block, a fixed sleeve, a lifting motor and a threaded rod, wherein the lifting block is fixedly connected onto the fixed slide rail, the fixed sleeve is fixedly connected into the fixed slide rail, the threaded rod is fixedly connected onto an output shaft of the lifting motor, the threaded rod and the lifting block are in threaded transmission, the two fixed slide rails are respectively in sliding connection with the two support frames, the two lifting blocks are respectively in sliding connection with the two support frames, and the two lifting motors are respectively in fixed connection with the two support frames.

The utility model has the advantages that:

the utility model provides a concrete placement pressure device for water conservancy construction, during the use, stick fixed connection will vibrate in two fixed slide rails, start adjustment motor, make the adjustment threaded rod rotate, adjust the interval of two support frames, later connect the feed bin to add the concrete by two, start two motors, make four helical blade all begin rotatoryly, because helical blade is that the screw thread type can make falling down that the material is faster, start two and promote the motor and adjust the height of two fixed slide rails, guarantee that the stick that vibrates immerses the position in the concrete and accord with the standard, remove the messenger and can guarantee that the stick that vibrates is in vertically all the time.

Drawings

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

fig. 2 is a schematic structural view of the pouring support frame of the present invention;

FIG. 3 is a schematic structural view of the distance adjusting mechanism of the present invention;

fig. 4 is a schematic structural view of the feeding and pressurizing mechanism of the present invention;

FIG. 5 is a sectional view of the feeding pressurizing mechanism of the present invention;

fig. 6 is the structural schematic diagram of the vibrating rod placing mechanism of the utility model.

In the figure: pouring the support frame 1; 1-1 of a support frame; 1-2 of a sliding sleeve; mounting grooves 1-3; a distance adjusting mechanism 2; adjusting a motor 2-1; 2-2 of a left sliding sleeve; 2-3 of a right sliding sleeve; 2-4 of a sliding support plate; 2-5 of a driving bevel gear; 2-6 parts of transmission bevel gear; rotating the rod A2-7; adjusting the threaded rod 2-8; 2-9 of an adjusting gear; a feeding pressurizing mechanism 3; a material receiving bin 3-1; a motor 3-2; 3-3 of a connecting sleeve; 3-4 of a discharge head; 3-5 of a transmission gear; rotating the rod B3-6; 3-7 of helical blades; a vibrating rod placing mechanism 4; a fixed slide rail 4-1; a lifting block 4-2; 4-3 of a fixed sleeve; 4-4 of a lifting motor; threaded rod 4-5.

Detailed Description

The present invention will be described in further detail with reference to fig. 1-6.

The first embodiment is as follows:

as shown in fig. 1-6, a concrete pouring pressurizing device for water conservancy construction comprises pouring support frames 1, a distance adjusting mechanism 2, feeding pressurizing mechanisms 3 and vibrating rod placing mechanisms 4, wherein the two pouring support frames 1 are respectively and fixedly connected to two ends of the distance adjusting mechanism 2, the two feeding pressurizing mechanisms 3 are respectively and fixedly connected to the two pouring support frames 1, and the two vibrating rod placing mechanisms 4 are respectively and slidably connected in the two pouring support frames 1;

when the vibrating rod is used, the vibrating rod is fixedly connected into the two fixed slide rails 4-1, the adjusting motors 2-1 are started to enable the adjusting threaded rods 2-8 to rotate, the distance between the two support frames 1-1 is adjusted, then the two material receiving bins 3-1 are used for adding concrete, the two motors 3-2 are started to enable the four helical blades 3-7 to start rotating, the helical blades 3-7 are threaded, materials can fall down more quickly, the two lifting motors 4-4 are started to adjust the height of the two fixed slide rails 4-1, the position of the vibrating rod immersed in the concrete is guaranteed to meet the standard, and the vibrating rod can be guaranteed to be vertical all the time when moving.

The second embodiment is as follows:

as shown in fig. 1-6, the pouring support frame 1 comprises a support frame 1-1, a sliding sleeve 1-2 and an installation groove 1-3, wherein the sliding sleeve 1-2 is fixedly connected to the support frame 1-1, and the installation groove 1-3 is arranged on the support frame 1-1;

the support frame 1-1 provides support for the device, and the arrangement of the sliding sleeve 1-2 can ensure that the vibrating rod placing mechanism 4 can slide in a certain range to protect the device from being damaged.

The third concrete implementation mode:

as shown in fig. 1-6, the distance adjusting mechanism 2 includes an adjusting motor 2-1, a left sliding sleeve 2-2, a right sliding sleeve 2-3, a sliding support plate 2-4, a driving bevel gear 2-5, a transmission bevel gear 2-6, a rotating rod a2-7, an adjusting threaded rod 2-8 and an adjusting gear 2-9, the left sliding sleeve 2-2 and the right sliding sleeve 2-3 are respectively and fixedly connected to two support frames 1-1, the sliding support plate 2-4 is slidably connected to the left sliding sleeve 2-2 and the right sliding sleeve 2-3, the driving bevel gear 2-5 is fixedly connected to the left sliding sleeve 2-2, the driving bevel gear 2-5 is fixedly connected to an output shaft of the adjusting motor 2-1, the driving bevel gear 2-5 is engaged with the transmission bevel gear 2-6 at the upper end for transmission, two transmission bevel gears 2-6 are respectively fixedly connected to two ends of a rotating rod A2-7, the rotating rod A2-7 is rotatably connected in a sliding support plate 2-4, the transmission bevel gear 2-6 positioned at the lower end is in meshing transmission with an adjusting gear 2-9, the adjusting gear 2-9 is fixedly connected on an adjusting threaded rod 2-8, the left end of the adjusting threaded rod 2-8 is rotatably connected in a support frame 1-1, the right end of the adjusting threaded rod 2-8 is in threaded transmission with the support frame 1-1, and the rotating rod A2-7 is rotatably connected in a mounting groove 1-3;

the adjusting motor 2-1 is started, the driving bevel gear 2-5 rotates to drive the two transmission bevel gears 2-6 and the rotating rod A2-7 to rotate into the transmission of the adjusting gear 2-9 to drive the adjusting threaded rod 2-8 to rotate, the distance between the two support frames 1-1 is adjusted, and the sliding support plate 2-4 also slides in the left sliding sleeve 2-2 and the right sliding sleeve 2-3.

The fourth concrete implementation mode:

as shown in fig. 1-6, the feeding pressurizing mechanism 3 comprises a material receiving bin 3-1, a motor 3-2 and a connecting sleeve 3-3, the material discharging device comprises material discharging heads 3-4, transmission gears 3-5, rotating rods B3-6 and helical blades 3-7, a motor 3-2 is fixedly connected to the upper end of a material receiving bin 3-1, two connecting sleeves 3-3 are fixedly connected to the lower end of the material receiving bin 3-1, two material discharging heads 3-4 are fixedly connected to the lower ends of the two connecting sleeves 3-3 respectively, two rotating rods B3-6 are rotatably connected to the material receiving bin 3-1 respectively, an output shaft of the motor 3-2 is fixedly connected with one rotating rod B3-6, two helical blades 3-7 are fixedly connected to two rotating rods B3-6 respectively, and four connecting sleeves 3-3 are fixedly connected to two supporting frames 1-1 respectively;

concrete is added from a material receiving bin 3-1, a motor 3-2 is started, and two rotating rods B3-6 start to rotate under the action of a transmission gear 3-5 to drive two helical blades 3-7 to rotate so as to accelerate and move down the concrete.

The fifth concrete implementation mode:

as shown in fig. 1-6, the vibrating rod placing mechanism 4 comprises a fixed slide rail 4-1 and a lifting block 4-2, the lifting device comprises a fixing sleeve 4-3, a lifting motor 4-4 and a threaded rod 4-5, wherein the lifting block 4-2 is fixedly connected to a fixed slide rail 4-1, the fixing sleeve 4-3 is fixedly connected to the fixed slide rail 4-1, the threaded rod 4-5 is fixedly connected to an output shaft of the lifting motor 4-4, the threaded rod 4-5 and the lifting block 4-2 are in threaded transmission, the two fixed slide rails 4-1 are respectively and slidably connected to two support frames 1-1, the two lifting blocks 4-2 are respectively and slidably connected to the two support frames 1-1, and the two lifting motors 4-4 are respectively and fixedly connected to the two support frames 1-1.

The lifting motor 4-4 is started, the threaded rod 4-5 is started to rotate, the lifting block 4-2 can be adjusted up and down due to threaded transmission, and therefore the vibrating rod fixed on the fixed sleeve 4-3 can be adjusted, and the vibrating rod can be selected in the market according to actual requirements.

The utility model relates to a concrete placement pressure device for water conservancy construction, its theory of use is: when in use, the vibrating rod is fixedly connected in the two fixed slide rails 4-1, the adjusting motor 2-1 is started to rotate the adjusting threaded rod 2-8, the distance between the two support frames 1-1 is adjusted, then the concrete is added into the two material receiving bins 3-1, the two motors 3-2 are started to enable the four helical blades 3-7 to start rotating, the helical blades 3-7 are threaded to enable materials to fall down more quickly, the two lifting motors 4-4 are started to adjust the height of the two fixed slide rails 4-1, the position of the vibrating rod immersed in the concrete is ensured to meet the standard, the vibrating rod can be ensured to be vertical all the time when moving, the support frames 1-1 provide support for the device, and the arrangement of the sliding sleeves 1-2 can ensure that the vibrating rod placing mechanism 4 can slide and protect the device from being damaged within a certain range, starting an adjusting motor 2-1, driving a bevel gear 2-5 to rotate to drive two transmission bevel gears 2-6 and a rotating rod A2-7 to rotate into the transmission of an adjusting gear 2-9 to enable an adjusting threaded rod 2-8 to rotate, adjusting the distance between two support frames 1-1, enabling a sliding support plate 2-4 to slide in a left sliding sleeve 2-2 and a right sliding sleeve 2-3, adding concrete from a receiving bin 3-1, starting the motor 3-2, enabling two rotating rods B3-6 to start to rotate under the action of a transmission gear 3-5 to drive two helical blades 3-7 to rotate to enable the concrete to move downwards and accelerate, starting a lifting motor 4-4 threaded rod 4-5 to rotate, and adjusting a lifting block 4-2 up and down due to thread transmission, thereby adjusting the vibrating rod fixed on the fixed sleeve 4-3.

Of course, the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and the changes, modifications, additions or replacements made by those skilled in the art within the scope of the present invention also belong to the protection scope of the present invention.

Claims (5)

1. The utility model provides a concrete placement pressure device for water conservancy construction, is including pouring support frame (1), its characterized in that: this a concrete placement pressure device for water conservancy construction still includes distance adjusting mechanism (2), feeding loading system (3) and vibrating rod placement mechanism (4), and two are pour support frame (1) fixed connection respectively at the both ends of distance adjusting mechanism (2), and two feeding loading system (3) are fixed connection respectively on two are pour support frame (1), and two vibrating rod placement mechanism (4) are sliding connection respectively in two are pour support frame (1).

2. A concrete placement pressure equipment for water conservancy construction according to claim 1 characterized in that: the pouring support frame (1) comprises a support frame (1-1), a sliding sleeve (1-2) and a mounting groove (1-3), the sliding sleeve (1-2) is fixedly connected to the support frame (1-1), and the mounting groove (1-3) is formed in the support frame (1-1).

3. A concrete placement pressure equipment for water conservancy construction according to claim 2 characterized in that: the distance adjusting mechanism (2) comprises an adjusting motor (2-1), a left sliding sleeve (2-2), a right sliding sleeve (2-3), a sliding support plate (2-4), a driving bevel gear (2-5), a transmission bevel gear (2-6), a rotating rod A (2-7), an adjusting threaded rod (2-8) and an adjusting gear (2-9), wherein the left sliding sleeve (2-2) and the right sliding sleeve (2-3) are respectively and fixedly connected onto the two support frames (1-1), the sliding support plate (2-4) is slidably connected into the left sliding sleeve (2-2) and the right sliding sleeve (2-3), the driving bevel gear (2-5) is fixedly connected onto the left sliding sleeve (2-2), the driving bevel gear (2-5) is fixedly connected onto an output shaft of the adjusting motor (2-1), the driving bevel gear (2-5) is in meshing transmission with the transmission bevel gear (2-6) positioned at the upper end, the two transmission bevel gears (2-6) are respectively and fixedly connected with the two ends of the rotating rod A (2-7), the rotating rod A (2-7) is rotatably connected in the sliding support plate (2-4), the transmission bevel gear (2-6) positioned at the lower end is in meshing transmission with the adjusting gear (2-9), the adjusting gear (2-9) is fixedly connected on the adjusting threaded rod (2-8), the left end of the adjusting threaded rod (2-8) is rotatably connected in the support frame (1-1), the right end of the adjusting threaded rod (2-8) is in threaded transmission with the support frame (1-1), and the rotating rod A (2-7) is rotatably connected in the mounting groove (1-3).

4. A concrete placement pressure equipment for water conservancy construction according to claim 3 characterized in that: the feeding pressurization mechanism (3) comprises a material receiving bin (3-1), a motor (3-2), connecting sleeves (3-3), material discharging heads (3-4), a transmission gear (3-5), rotating rods B (3-6) and helical blades (3-7), the motor (3-2) is fixedly connected to the upper end of the material receiving bin (3-1), the two connecting sleeves (3-3) are fixedly connected to the lower end of the material receiving bin (3-1), the two material discharging heads (3-4) are respectively and fixedly connected to the lower ends of the two connecting sleeves (3-3), the two rotating rods B (3-6) are respectively and rotatably connected to the material receiving bin (3-1), an output shaft of the motor (3-2) is fixedly connected with one rotating rod B (3-6), the two helical blades (3-7) are respectively and fixedly connected to the two rotating rods B (3-6), the four connecting sleeves (3-3) are respectively and fixedly connected to the two supporting frames (1-1).

5. A concrete placement pressure equipment for water conservancy construction according to claim 4, characterized in that: the vibrating rod placing mechanism (4) comprises fixed slide rails (4-1), lifting blocks (4-2), fixed sleeves (4-3), lifting motors (4-4) and threaded rods (4-5), wherein the lifting blocks (4-2) are fixedly connected onto the fixed slide rails (4-1), the fixed sleeves (4-3) are fixedly connected into the fixed slide rails (4-1), the threaded rods (4-5) are fixedly connected onto output shafts of the lifting motors (4-4), the threaded rods (4-5) and the lifting blocks (4-2) are in threaded transmission, the two fixed slide rails (4-1) are respectively in sliding connection with the two support frames (1-1), the two lifting blocks (4-2) are respectively in sliding connection with the two support frames (1-1), and the two lifting motors (4-4) are respectively in fixed connection with the two support frames (1-1) The above.

Images