CN210764011U - Stacker crane for producing microporous lightweight concrete heat-insulation energy-saving composite building blocks - Google Patents

Abstract

The utility model discloses a production micropore lightweight concrete outage energy-saving hacking machine for composite block, including counter weight bottom plate, support post and diaphragm, the counter weight bottom plate top has support post and support post interior top to be fixed with No. two gear motor through the mounting bracket through the bolt fastening, the support post top has slewing bearing and slewing bearing top to have the diaphragm through the bolt fastening, the welding of diaphragm one end has places the board and places the board top and be fixed with wire rope around the dish through the mounting bracket, wire rope is fixed with gear motor through the mounting bracket around a set one end, one side output shaft that another pot head of diaphragm was equipped with electric hydraulic cylinder and electric hydraulic cylinder has the accessory plate through the bolt fastening. The utility model discloses simple structure, convenient operation, cost, maintenance cost are low, are fit for being extensively promoted and use.

Description

Stacker crane for producing microporous lightweight concrete heat-insulation energy-saving composite building blocks

Technical Field

The utility model relates to a hacking machine technical field, in particular to production micropore lightweight concrete outage energy-conserving hacking machine for composite block.

Background

The stacker crane is equipment for stacking goods on a tray and a pallet according to a certain arrangement, is high in manufacturing cost and high in later maintenance and repair cost due to the fact that the conventional stacker crane is structurally auxiliary and is not suitable for stacking the microporous lightweight concrete heat-insulation energy-saving composite building blocks, and therefore the stacker crane for producing the microporous lightweight concrete heat-insulation energy-saving composite building blocks is provided.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a production micropore lightweight concrete outage energy-conserving hacking machine for composite block can effectively solve the problem in the background art.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a stacker crane for producing microporous lightweight concrete heat-insulating energy-saving composite building blocks comprises a counterweight bottom plate, a supporting upright post and a transverse plate, the top of the counterweight bottom plate is fixed with a support upright post through a bolt, the inner top of the support upright post is fixed with a second speed reducing motor through a mounting rack, the top of the supporting upright post is fixed with a slewing bearing through a bolt, the top of the slewing bearing is fixed with a transverse plate through a bolt, a placing plate is welded at one end of the transverse plate, a steel wire rope winding disc is fixed at the top of the placing plate through a mounting frame, one end of the steel wire rope winding disc is fixed with a first speed reducing motor through a mounting frame, the other end of the transverse plate is sleeved with an electric hydraulic cylinder, an output shaft at one side of the electric hydraulic cylinder is fixed with an auxiliary plate through a bolt, the auxiliary plate is characterized in that auxiliary rods are fixed at two ends of one side of the auxiliary plate through bolts, a frame is arranged at the lower end of the auxiliary plate, air cylinders are installed on two sides of the frame through bolts, and clamping plates are arranged on two sides of the interior of the frame.

Furthermore, one end of the top of the transverse plate is fixedly provided with a first pulley through a bolt, the other end of the top of the transverse plate is fixedly provided with a second pulley through a bolt, the top of the auxiliary plate is fixedly provided with a third pulley through a bolt, and one side of the auxiliary plate is provided with a fourth pulley through a mounting groove.

Furthermore, a steel wire rope is wound and fixed on the outer side of the steel wire rope winding disc, and one end of the steel wire rope is fixed on the top of the frame through a fixing buckle.

Furthermore, an output end of one side of the first speed reducing motor is connected with a rotating shaft of the steel wire rope winding disc through a bolt, and an output shaft of the top of the second speed reducing motor is fixed to the bottom of the transverse plate through a bolt.

Further, the output end of one side of the air cylinder is fixed on one side of the clamping plate through a bolt, and the clamping teeth are arranged on the other side of the clamping plate and are multiple in number.

Compared with the prior art, the utility model discloses following beneficial effect has:

1. through setting up gear motor and slewing bearing No. two, the personnel open No. two gear motor and can drive the diaphragm and rotate, and slewing bearing can improve diaphragm pivoted smoothness nature and its structural stability.

2. Through setting up gear motor and wire rope coiling dish, personnel open gear motor and drive wire rope coiling dish and rotate, and wire rope coiling dish corotation and reversal pass through the steel wire rope and drive the frame and reciprocate.

3. Through setting up cylinder and splint, personnel control cylinder promotes splint, can hold micropore light concrete heat-insulating energy-saving composite block, and the micropore light concrete heat-insulating energy-saving composite block landing that a plurality of latches can prevent to hold.

Drawings

Fig. 1 is the utility model relates to a production micropore lightweight concrete breaks heat energy-conserving hacking machine's overall structure schematic diagram for composite block.

Fig. 2 is the utility model relates to a production micropore lightweight concrete cuts off heat energy-conserving for composite block hacking machine diaphragm, accessory plate and places board schematic structure.

Fig. 3 is the utility model relates to a production micropore lightweight concrete breaks heat energy-conserving for composite block hacking machine's support post structural schematic diagram.

Fig. 4 is the utility model discloses a frame construction schematic diagram of production micropore lightweight concrete outage energy-conserving hacking machine for composite block.

In the figure: 1. a counterweight bottom plate; 2. supporting the upright post; 3. a transverse plate; 4. placing the plate; 5. an auxiliary plate; 6. coiling a steel wire rope; 7. a first speed reduction motor; 8. an electric hydraulic cylinder; 9. an auxiliary lever; 10. a frame; 11. a cylinder; 12. a splint; 13. a steel wire rope; 14. a second speed reduction motor; 15. a slewing bearing; 16. clamping teeth; 17. a first pulley; 18. a second pulley; 19. a third pulley; 20. and a fourth pulley.

Detailed Description

In order to make the technical means, creation features, achievement purposes and functions of the present invention easy to understand, the present invention is further described below with reference to the following embodiments.

As shown in fig. 1-4, a stacker crane for producing microporous lightweight concrete adiabatic energy-saving composite blocks comprises a counterweight bottom plate 1, a support upright post 2 and a transverse plate 3, wherein the top of the counterweight bottom plate 1 is fixed with the support upright post 2 through bolts, the inner top of the support upright post 2 is fixed with a second speed reduction motor 14 through a mounting frame, the top of the support upright post 2 is fixed with a slewing bearing 15 through bolts, the top of the slewing bearing 15 is fixed with the transverse plate 3 through bolts, one end of the transverse plate 3 is welded with a placing plate 4, the top of the placing plate 4 is fixed with a steel wire rope winding disc 6 through the mounting frame, one end of the steel wire rope winding disc 6 is fixed with a first speed reduction motor 7 through the mounting frame, the other end of the transverse plate 3 is sleeved with an electric hydraulic cylinder 8, an auxiliary plate 5 is fixed with an output shaft at one side of the electric hydraulic cylinder 8 through bolts, auxiliary rods 9, the air cylinder 11 is installed on two sides of the frame 10 through bolts, and the clamping plates 12 are arranged on two sides inside the frame 10.

One end of the top of the transverse plate 3 is fixed with a first pulley 17 through a bolt, the other end of the top of the transverse plate 3 is fixed with a second pulley 18 through a bolt, the top of the auxiliary plate 5 is fixed with a third pulley 19 through a bolt, and one side of the auxiliary plate 5 is provided with a fourth pulley 20 through an installation groove.

In this embodiment, as shown in fig. 2, the first pulley 17, the second pulley 18 and the third pulley 19 prevent the wire rope 13 from contacting other objects, increase friction force, and make it difficult to move, and the fourth pulley 20 prevents the wire rope 13 from being bent and positioned on the auxiliary plate 5 to be rubbed.

Wherein, the steel wire rope 13 is fixed on the outer side of the steel wire coiling disc 6 in a winding way, and one end of the steel wire rope 13 is fixed on the top of the frame 10 through a fixing buckle.

In this embodiment, as shown in fig. 1, the forward and reverse rotation of the steel wire winding disk 6 can drive the steel wire 13 to contract and expand, so as to drive the frame 10 to move up and down.

The output end of one side of the first speed reducing motor 7 is connected with the rotating shaft of the steel wire rope winding disc 6 through a bolt, and the output shaft of the top of the second speed reducing motor 14 is fixed to the bottom of the transverse plate 3 through a bolt.

In this embodiment, as shown in fig. 2 and 3, the first reduction motor 7 can drive the steel wire rope to rotate around the reel 6, and the second reduction motor 14 can drive the transverse plate 3 to rotate.

The output end of one side of the cylinder 11 is fixed on one side of the clamping plate 12 through a bolt, and the clamping teeth 16 are arranged on the other side of the clamping plate 12 and the number of the clamping teeth 16 is multiple.

In this embodiment, as shown in fig. 4, the cylinder 11 can push the clamping plate 12 to move, so as to clamp the composite block, and the plurality of latches 16 make it not easy to slip.

It should be noted that the utility model relates to a production micropore lightweight concrete heat-breaking energy-saving composite block uses the hacking machine, in operation, personnel use the power cord to connect this product with external power supply, use the trachea to connect cylinder 11 with external air supply equipment, personnel open No. two gear motor 14 and drive diaphragm 3 and rotate, and drive auxiliary plate 5 through electric hydraulic cylinder 8 and move, make frame 10 move to micropore lightweight concrete heat-breaking energy-saving composite block directly over, auxiliary rod 9 can improve the structural stability of auxiliary plate 5, personnel open No. one gear motor 7 and drive wire rope reel 6 and rotate, put down frame 10 through wire rope 13 until falling on micropore lightweight concrete heat-breaking energy-saving composite block, personnel control cylinder 11 promotes splint 12 and move, compound micropore lightweight concrete heat-breaking energy-saving composite block centre gripping, fix, a plurality of latch 16 can prevent micropore lightweight concrete heat-breaking energy-saving composite block from landing, a person controls the first speed reducing motor 7 to rotate reversely, the frame 10 is pulled to move upwards through the steel wire rope 13, the person controls the second speed reducing motor 14 to rotate again, the electric hydraulic cylinder 8 stretches and retracts, the microporous lightweight concrete heat-insulation and energy-saving composite building block is moved to the supporting plate or the pallet, the first pulley 17, the second pulley 18 and the third pulley 19 enable the steel wire rope 13 not to be in contact with other objects, friction force is increased, and therefore the supporting plate is difficult to move, the fourth pulley 20 can prevent the steel wire rope 13 from being bent to be positioned on the auxiliary plate 5 to be abraded, and the slewing bearing 15 (products of Jiangsu double positive machinery Limited) can improve the smoothness of rotation of the transverse plate 3 and the structural stability of the transverse.

The basic principles and the main features of the invention and the advantages of the invention have been shown and described above. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (5)

1. The utility model provides a production micropore lightweight concrete breaks heat energy-conserving hacking machine for composite block, includes counter weight bottom plate (1), support post (2) and diaphragm (3), its characterized in that: the balance weight base plate is characterized in that a support upright post (2) is fixed at the top of the balance weight base plate (1) through bolts, a second speed reducing motor (14) is fixed at the inner top of the support upright post (2) through a mounting rack, a slewing bearing (15) is fixed at the top of the support upright post (2) through bolts, a transverse plate (3) is fixed at the top of the slewing bearing (15) through bolts, a placing plate (4) is welded at one end of the transverse plate (3), a steel wire rope winding disc (6) is fixed at the top of the placing plate (4) through the mounting rack, a first speed reducing motor (7) is fixed at one end of the steel wire rope winding disc (6) through the mounting rack, an electric hydraulic cylinder (8) is sleeved at the other end of the transverse plate (3), an auxiliary plate (5) is fixed at one side output shaft of the electric hydraulic cylinder (8) through bolts, auxiliary rods (9), the air cylinder (11) is installed on the two sides of the frame (10) through bolts, and clamping plates (12) are arranged on the two sides inside the frame (10).

2. The stacker crane for producing the microporous lightweight concrete heat-insulating energy-saving composite building block according to claim 1, wherein the stacker crane comprises: one end of the top of the transverse plate (3) is fixed with a first pulley (17) through a bolt, the other end of the top of the transverse plate (3) is fixed with a second pulley (18) through a bolt, the top of the auxiliary plate (5) is fixed with a third pulley (19) through a bolt, and one side of the auxiliary plate (5) is provided with a fourth pulley (20) through an installation groove.

3. The stacker crane for producing the microporous lightweight concrete heat-insulating energy-saving composite building block according to claim 1, wherein the stacker crane comprises: and a steel wire rope (13) is wound and fixed on the outer side of the steel wire rope winding disc (6), and one end of the steel wire rope (13) is fixed on the top of the frame (10) through a fixing buckle.

4. The stacker crane for producing the microporous lightweight concrete heat-insulating energy-saving composite building block according to claim 1, wherein the stacker crane comprises: the output end of one side of the first speed reducing motor (7) is connected with a rotating shaft of the steel wire rope winding disc (6) through a bolt, and the output shaft of the top of the second speed reducing motor (14) is fixed to the bottom of the transverse plate (3) through a bolt.

5. The stacker crane for producing the microporous lightweight concrete heat-insulating energy-saving composite building block according to claim 1, wherein the stacker crane comprises: inside auxiliary rod (9) one end is fixed in diaphragm (3), cylinder (11) one side output is fixed in splint (12) one side through the bolt, the quantity that latch (16) and latch (16) were seted up to splint (12) opposite side is a plurality of.

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