CN111496165A

CN111496165A - Forging equipment for building materials

Info

Publication number: CN111496165A
Application number: CN202010375155.9A
Authority: CN
Inventors: 李素莲
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-05-05
Filing date: 2020-05-05
Publication date: 2020-08-07

Abstract

The invention relates to the field of buildings, in particular to a forging device for building materials. The material can be forged alternately, so that the forging efficiency of the material is improved conveniently; meanwhile, materials with different specifications can be fixed, and adjustment can be performed according to actual conditions; while the speed of the forging of the material can be varied. The device comprises a power source assembly, a fixed assembly, a forging assembly and a chassis assembly, wherein when a planet gear II and a planet gear I move, a sliding rod I is forged respectively; the forging slide bar II drives the forging slide bar I to push the spring I; forging a sliding rod pushing spring II, and further forging the sliding rod pushing spring I; the forging slide rod pushing spring II drives the forging rod I; moving the forging rod II downwards, and further forging the rod I; the contact of the forging rod II and the material is further realized, the material is forged, meanwhile, in the process of forging the material to be forged, the motion relation between the forging rod I and the forging rod II is the new alternative contact with the material, and the forging efficiency of the material is further improved conveniently.

Description

Forging equipment for building materials

Technical Field

The invention relates to the field of buildings, in particular to a forging device for building materials.

Background

The forging equipment for building materials is a common equipment in the field of building, but the general forging equipment for building materials has single function.

Disclosure of Invention

The invention aims to provide a material forging device for buildings, which can realize the alternative forging of materials and further conveniently improve the forging efficiency of the materials; meanwhile, materials with different specifications can be fixed, and adjustment can be performed according to actual conditions; while the speed of the forging of the material can be varied.

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

the utility model provides a material forging equipment for building, includes power supply assembly, fixed assembly, forges and beats assembly, chassis assembly, the power supply assembly is connected with the chassis assembly, and fixed assembly is connected with the chassis assembly, forges and beats the assembly and is connected with the chassis assembly.

As a further optimization of the technical scheme, the invention relates to a material forging device for buildings, wherein a power source assembly comprises a power bottom plate, an output friction wheel, a middle-end friction wheel, an input friction wheel, an auxiliary slide rod, a spherical clamping groove, a driving slide rod, a spherical clamp push spring, a prismatic slide rod, a first rotating rod, a first clamping groove, a second rotating rod, a first sleeve, a first inner end clamping rod push spring, a second clamping groove, a second inner end clamping rod push spring, a third rotating rod, a swinging rotating rod, a first clutch rod, a second clutch rod slide rod, a clutch rod push spring, a first straight tooth, a second straight tooth, an input motor, a clutch clamp, a hinged rotor, a rectangular boss, a middle-end rotating column and a clamp push spring, the middle-end friction wheel and the output friction wheel are rotationally connected with the power bottom plate, and the output friction wheel is in friction transmission, the input friction wheel is in friction transmission with the middle-end friction wheel, the input friction wheel is in sliding connection with a prismatic sliding rod, the prismatic sliding rod is in rotating connection with the power bottom plate, the auxiliary sliding rod is fixedly connected with the power bottom plate, a spherical clamping groove is formed in the auxiliary sliding rod, a driving sliding rod is in sliding connection with the auxiliary sliding rod, the driving sliding rod is in matching connection with the input friction wheel, a first rotating rod is fixedly connected with the prismatic sliding rod, a spherical clamp is in sliding connection with the driving sliding rod, the spherical clamp is in matching connection with the spherical clamping groove, a spherical clamp push spring is arranged between the spherical clamp and the driving sliding rod, a second inner clamping rod is in sliding connection with the first rotating rod, a second inner clamping rod push spring is arranged between the second inner clamping rod and the first rotating rod, the second inner clamping rod is in sleeve connection with the second inner clamping rod, the second clamping groove is arranged on the first rotating rod, and the first clamping groove is, a first rotating rod slide bar is rotatably connected with one sleeve, a first inner clamping rod is slidably connected with a first sleeve, a first inner clamping rod push spring is connected with a first inner clamping rod in a sleeved mode, a first inner clamping rod push spring is arranged between the first inner clamping rod and the first sleeve, a first inner clamping rod is matched and connected with a clamping groove, a first rotating rod is hinged with a third rotating rod slide bar, a third rotating rod slide bar is slidably connected with a swinging rotating rod, the swinging rotating rod is fixedly connected with a first clutch rod, a first clutch rod is rotatably connected with a power bottom plate, a middle rotating rod is rotatably connected with the swinging rotating rod, a rectangular boss is rotatably connected with the middle rotating rod, a hinged rotor is rotatably connected with the middle rotating rod, a third rotating rod slide bar is rotatably connected with the hinged rotor, a clutch clamp is matched and connected with the first clutch rod, a clutch clamp is slidably connected with a second clutch rod, a clamp push spring is arranged between the clutch clamp and the second clutch rod, and the second clutch rod slide rod is, the clutch rod push spring is connected with the clutch rod sliding rod in a sleeved mode, the clutch rod push spring is arranged between the clutch rod II and the clutch rod sliding rod, the straight tooth I is fixedly connected with the clutch rod sliding rod, the straight tooth I is in meshed transmission with the straight tooth II, and the straight tooth II is fixedly connected with the input motor.

As a further optimization of the technical scheme, the invention relates to a material forging device for buildings, wherein a fixed combination comprises an N-shaped frame, a lower end rotating rod, a manual rotating disc, a fixed rotating disc, a middle end bearing rod, a hinged fixed rod, an auxiliary sliding rod, a hinged column, a lower end sliding groove, a first bevel gear, a second bevel gear, an inner end sliding column and an inner end sliding column pushing spring, the lower end rotating rod is rotatably connected with the N-shaped frame, the manual rotating disc is rotatably connected with the N-shaped frame, the fixed rotating disc is rotatably connected with the manual rotating disc, the middle end bearing rod is slidably connected with the fixed rotating disc, the hinged fixed rod is hinged with the middle end bearing rod, the hinged fixed rod is slidably connected with the hinged column, the hinged column is slidably connected with the inner end sliding column, the inner end sliding column pushing spring is sleeved with the inner end sliding column, the inner end sliding column is fixedly connected with the auxiliary sliding rod, the auxiliary sliding rod is slidably connected with, the auxiliary sliding rod is connected with the lower end sliding groove in a sliding fit mode, the first bevel gear is fixedly connected with the fixed rotary table, the second bevel gear is in meshed transmission with the first bevel gear, and the second bevel gear is fixedly connected with the lower end rotating rod.

As a further optimization of the technical scheme, the material forging equipment for the building comprises a first support, a second support, a third support, a fourth support, a fifth support, a support rotary column, a first limit sleeve, a second limit sleeve, a first sun wheel, a first planet wheel, a first forging rod, a second sun wheel, a second planet wheel, a first planet wheel rotary rod, a first forging slide rod, a second forging slide rod, a first forging slide rod pushing spring, a second forging slide rod pushing spring and a second planet wheel rotary rod, wherein the second support is fixedly connected with the first support, the third support is fixedly connected with the second support, the fifth support is fixedly connected with the fourth support, the fifth support is fixedly connected with the second support, the first limit sleeve and the second limit sleeve are rotatably connected with the support rotary column, the first forging rod and the second forging rod are respectively connected with the first limit sleeve and the second limit sleeve in a matching manner, and the first sun wheel is fixedly connected with the rotary rod, a second planet wheel rotating rod is rotatably connected with a third support, a second planet wheel rotating rod is rotatably connected with a second planet wheel, the second planet wheel is in matched connection with a second sun wheel, the second planet wheel is fixedly connected with a first planet wheel rotating rod, the first planet wheel rotating rod is rotatably connected with the second planet wheel, the second planet wheel is in matched connection with a first sun wheel, the first planet wheel rotating rod is rotatably connected with the third support, a second forging slide rod is fixedly connected with the second planet wheel, the second forging slide rod is in sliding connection with the first forging slide rod, a second forging slide rod pushing spring is arranged between the second forging slide rod and the first forging rod, the second forging slide rod is in sliding connection with the first forging slide rod, the first forging slide rod pushing spring is arranged between the second forging slide rod and the first forging slide rod, and the first forging slide rod is fixedly connected with the second planet wheel,

as a further optimization of the technical scheme, the material forging equipment for the building comprises an underframe body, an underframe support I, an underframe support II, an underframe belt I, an underframe belt II and an underframe support III, wherein the underframe support I, the underframe support II and the underframe support III are fixedly connected with the underframe body, the underframe belt I is arranged between a planetary wheel rotating rod I and a lower end rotating rod, the underframe belt II is arranged between an output friction wheel and the lower end rotating rod, a power bottom plate is fixedly connected with the underframe support III, an N-shaped frame is slidably connected with the underframe body, the underframe support I is fixedly connected with the support I, and the underframe support II is fixedly connected with a support V.

The material forging equipment for the building has the beneficial effects that:

the invention relates to a material forging device for buildings, wherein an output friction wheel rotates to drive an underframe belt II to move, and further drives a lower end rotating rod to move, and further drives an underframe belt I to move through the lower end rotating rod, and further drives a planet wheel rotating rod I to move through the underframe belt I, and further drives a planet wheel II to move through the planet wheel rotating rod I, and further drives a sun wheel II to rotate, and further drives a planet wheel I to move through the planet wheel rotating rod I, and further drives another planet wheel II to move through another planet wheel rotating rod I which is connected with the sun wheel I, and further drives other planet wheel II, planet wheel I, sun wheel I and sun wheel II to move respectively, and when the planet wheel II and the planet wheel I move, the planet wheel I and the sun wheel II are respectively forged through a first sliding rod; the forging slide bar II drives the forging slide bar I to push the spring I; forging a sliding rod pushing spring II, and further forging the sliding rod pushing spring I; the forging slide rod pushing spring II drives the forging rod I; moving the forging rod II downwards, and further forging the rod I; the contact of the forging rod II and the material is further realized, the material is forged, meanwhile, in the process of forging the material to be forged, the motion relation between the forging rod I and the forging rod II is the new alternative contact with the material, and the forging efficiency of the material is further improved conveniently.

Drawings

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

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

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

FIG. 3 is a schematic illustration of the power source assembly of the present invention;

FIG. 4 is a schematic illustration of the power source assembly of the present invention;

FIG. 5 is a schematic illustration of the power source assembly of the present invention;

FIG. 6 is a schematic view of the fixed assembly of the present invention;

FIG. 7 is a schematic view of the fixed assembly of the present invention;

FIG. 8 is a schematic view of the mounting assembly of the present invention;

FIG. 9 is a schematic view of a forging assembly of the present invention;

FIG. 10 is a schematic view of a forging assembly of the present invention;

FIG. 11 is a schematic view of a forging assembly of the present invention;

FIG. 12 is a schematic view of a forging assembly of the present invention;

fig. 13 is a schematic structural view of the chassis assembly of the present invention.

In the figure: a power source assembly 1; a power backplane 1-1; an output friction wheel 1-2; 1-3 middle friction wheels; inputting a friction wheel 1-4; 1-5 auxiliary sliding rods; 1-6 parts of a spherical clamping groove; driving the slide bar 1-7; 1-8 parts of spherical clips; 1-9 parts of a spherical clip push spring; 1-10 of prismatic slide bar; 1-11 of a rotating rod I; 1-12 of a rotating rod sliding rod I; 1-13 of a first clamping groove; a second rotating rod sliding rod 1-14; 1-15 parts of a first sleeve; the inner end clamping rod I is 1-16; the inner end clamping rod pushes the spring 1-17; a second clamping groove 1-18; the inner end of the clamping rod II is 1-19; a second push spring 1-20 of the inner end clamping rod; a rotating rod sliding rod III 1-21; swing the rotary rod 1-22; the first clutch lever 1-23; a second clutch lever 1-24; 1-25 of a clutch lever slide bar; clutch lever push spring 1-26; 1-27 straight teeth I; 1-28 parts of straight teeth II; input motors 1-29; 1-30 of clutch clips; articulated rotors 1-31; 1-32 of rectangular bosses; 1-33 middle-end rotary columns; clip push springs 1-34; a fixed assembly 2; 2-1 of an N-shaped frame; a lower end rotating rod 2-2; 2-3 of a manual turntable; fixing a rotary table 2-4; 2-5 of a middle-end bearing rod; hinged fixed rods 2-6; 2-7 of auxiliary sliding rod; hinge columns 2-8; a lower end chute 2-9; 2-10 parts of a first bevel gear; 2-11 parts of a second bevel gear; 2-12 inner end sliding columns; the inner end sliding column pushes springs 2-13; the forging assembly 3; 3-1 of a first bracket; 3-3 of a second bracket; 3-4 parts of a bracket III; 3-5 of a bracket; 3-6 parts of a bracket; 3-7 of support rotary columns; 3-8 parts of a first limiting sleeve; 3-9 parts of a second limiting sleeve; 3-10 parts of a first sun gear; 3-11 of a first planet wheel; forging a first rod 3-12; forging a second rod 3-13; 3-14 parts of a second sun gear; 3-15 parts of planet wheel II; 3-16 planetary wheel rotating rods; forging a first sliding rod 3-17; forging a second sliding rod 3-18; forging a first push spring 3-19 of the slide rod; forging a sliding rod push spring II by 3-20; a planet wheel rotating rod II 3-21; a chassis assembly 4; a chassis body 4-1; 4-2 of a first underframe support; 4-3 of a second underframe support; 4-4 parts of a first underframe belt; 4-5 of a second underframe belt; and 4-6 of underframe supports.

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 13, and a building material forging apparatus includes a power source assembly 1, a fixing assembly 2, a forging assembly 3, and a base frame assembly 4, where the power source assembly 1 is connected to the base frame assembly 4, the fixing assembly 2 is connected to the base frame assembly 4, and the forging assembly 3 is connected to the base frame assembly 4.

The second embodiment is as follows:

the first embodiment is further described with reference to fig. 1-13, and the power source assembly 1 includes a power bottom plate 1-1, an output friction wheel 1-2, a middle friction wheel 1-3, an input friction wheel 1-4, an auxiliary slide bar 1-5, a ball-shaped slot 1-6, a driving slide bar 1-7, a ball-shaped clip 1-8, a ball-shaped clip push spring 1-9, a prismatic slide bar 1-10, a first rotating bar 1-11, a first rotating bar slide bar 1-12, a first slot 1-13, a second rotating bar slide bar 1-14, a first sleeve 1-15, a first inner end clamping bar 1-16, a first inner end clamping bar push spring 1-17, a second slot 1-18, a second inner end clamping bar 1-19, a second inner end clamping bar push spring 1-20, a second sleeve 1-15, a second inner end clamping bar push spring 1-17, a second, A rotating rod sliding rod III 1-21, a swinging rotating rod 1-22, a clutch rod I1-23, a clutch rod II 1-24, a clutch rod sliding rod 1-25, a clutch rod push spring 1-26, a straight tooth I1-27, a straight tooth II 1-28, an input motor 1-29, a clutch clip 1-30, a hinged rotor 1-31, a rectangular boss 1-32, a middle end rotating column 1-33, a clip push spring 1-34, a middle end friction wheel 1-3, an output friction wheel 1-2 and a power bottom plate 1-1 are rotationally connected, an output friction wheel 1-2 and the middle end friction wheel 1-3 are in friction transmission, an input friction wheel 1-4 and a sliding rod prism 1-10 are in sliding connection, a prism sliding rod 1-10 and a power bottom plate 1-1 are rotationally connected, an auxiliary sliding rod 1-5 is fixedly connected with a power bottom plate 1-1, a spherical clamping groove 1-6 is arranged on the auxiliary sliding rod 1-5, a driving sliding rod 1-7 is connected with the auxiliary sliding rod 1-5 in a sliding manner, a driving sliding rod 1-7 is connected with an input friction wheel 1-4 in a matching manner, a rotating rod 1-11 is fixedly connected with a prismatic sliding rod 1-10, a spherical clamp 1-8 is connected with the driving sliding rod 1-7 in a sliding manner, a spherical clamp 1-8 is connected with the spherical clamping groove 1-6 in a matching manner, a spherical clamp push spring 1-9 is arranged between the spherical clamp 1-8 and the driving sliding rod 1-7, an inner end clamping rod II 1-19 is connected with the rotating rod I1-11 in a sliding manner, and an inner end clamping rod push spring II 1-20 is arranged between the inner end clamping rod II 1-19 and the, the inner end clamping rod push spring II 1-20 is connected with the inner end clamping rod II 1-19 in a sleeved mode, the inner end clamping rod II 1-19 is connected with the clamping groove II 1-18 in a matched mode, the clamping groove II 1-18 is arranged on the rotating rod I1-12, the clamping groove I1-13 is arranged on the rotating rod I1-14, the rotating rod I1-12 is rotatably connected with the sleeve I1-15, the inner end clamping rod I1-16 is slidably connected with the sleeve I1-15, the inner end clamping rod push spring I1-17 is connected with the inner end clamping rod I1-16 in a sleeved mode, the inner end clamping rod push spring I1-17 is arranged between the inner end clamping rod I1-16 and the sleeve I1-15, the inner end clamping rod I1-16 is connected with the clamping groove I1-13 in a matched mode, the rotating rod I1-11 is connected with the rotating rod III 1-21 in a hinged mode, a rotating rod three 1-21 is connected with a swinging rotating rod 1-22 in a sliding way, the swinging rotating rod 1-22 is fixedly connected with a clutch rod one 1-23, the clutch rod one 1-23 is connected with a power bottom plate 1-1 in a rotating way, a middle rotating column 1-33 is connected with the swinging rotating rod 1-22 in a rotating way, a rectangular boss 1-32 is connected with the middle rotating column 1-33 in a rotating way, a hinged rotor 1-31 is connected with the middle rotating column 1-33 in a rotating way, the rotating rod three 1-21 is connected with the hinged rotor 1-31 in a rotating way, a clutch clamp 1-30 is connected with the clutch rod one 1-23 in a matching way, the clutch clamp 1-30 is connected with a clutch rod two 1-24 in a sliding way, a clamp push spring 1-34 is arranged between the clutch clamp 1-30 and the clutch rod two 1-24, the clutch rod two 1-24 is connected with the clutch rod sliding rod 1-, the clutch lever push springs 1-26 are connected with the clutch lever sliding rods 1-25 in a sleeved mode, the clutch lever push springs 1-26 are arranged between the clutch lever II 1-24 and the clutch lever sliding rods 1-25, the straight teeth I1-27 are fixedly connected with the clutch lever sliding rods 1-25, the straight teeth I1-27 are in meshed transmission with the straight teeth II 1-28, and the straight teeth II 1-28 are fixedly connected with the input motors 1-29.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1-13, and the embodiment further describes the first embodiment, where the fixed assembly 2 includes an N-shaped frame 2-1, a lower rotating rod 2-2, a manual rotating disc 2-3, a fixed rotating disc 2-4, a middle bearing rod 2-5, a hinge fixed rod 2-6, an auxiliary sliding rod 2-7, a hinge column 2-8, a lower sliding chute 2-9, a first bevel gear 2-10, a second bevel gear 2-11, an inner sliding column 2-12, and an inner sliding column push spring 2-13, the lower rotating rod 2-2 is rotatably connected with the N-shaped frame 2-1, the manual rotating disc 2-3 is rotatably connected with the N-shaped frame 2-1, the fixed rotating disc 2-4 is rotatably connected with the manual rotating disc 2-3, the middle bearing rod 2-5 is slidably connected with the fixed rotating disc 2-4, the hinged fixed rod 2-6 is hinged with the middle end bearing rod 2-5, the hinged fixed rod 2-6 is connected with a hinged column 2-8 in a sliding fit mode, the hinged column 2-8 is connected with an inner end sliding column 2-12 in a sliding mode, an inner end sliding column push spring 2-13 is connected with the inner end sliding column 2-12 in a sleeved mode, the inner end sliding column 2-12 is fixedly connected with an auxiliary sliding rod 2-7, the auxiliary sliding rod 2-7 is connected with a fixed rotary table 2-4 in a sliding mode, a lower end sliding groove 2-9 is formed in a manual rotary table 2-3, the auxiliary sliding rod 2-7 is connected with a lower end sliding groove 2-9 in a sliding fit mode, a first conical tooth 2-10 is fixedly connected with the fixed rotary table 2-4, a second conical tooth 2-11 is in meshing transmission with the first conical tooth 2-10, and the second conical tooth 2-.

The fourth concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 13, and the embodiment further describes the first embodiment, where the forging assembly 3 includes a first support 3-1, a second support 3-3, a third support 3-4, a fourth support 3-5, a fifth support 3-6, a support rotary column 3-7, a first limiting sleeve 3-8, a second limiting sleeve 3-9, a first sun gear 3-10, a first planet gear 3-11, a first forging rod 3-12, a second forging rod 3-13, a second sun gear 3-14, a second planet gear 3-15, a first planet gear rotary rod 3-16, a first forging rod 3-17, a second forging rod 3-18, a first forging rod pushing spring 3-19, a second forging rod pushing spring 3-20, and a second planet gear rotary rod 3-21, where the second support 3-3 is fixedly connected to the first support 3-1, a third support 3-4 is fixedly connected with a second support 3-3, a fifth support 3-6 is fixedly connected with a fourth support 3-5, a rotary column 3-7 of the support, a fifth support 3-6 and a second support 3-3 are fixedly connected, a first limit sleeve 3-8 and a second limit sleeve 3-9 are rotatably connected with the rotary column 3-7 of the support, a first forging rod 3-12 and a second forging rod 3-13 are respectively connected with the first limit sleeve 3-8 and the second limit sleeve 3-9 in a matching manner, a first sun wheel 3-10 is fixedly connected with a second planet wheel rotary rod 3-21, a second planet wheel rotary rod 3-21 is rotatably connected with the third support 3-4, a second planet wheel rotary rod 3-21 is rotatably connected with a second planet wheel 3-15, and a second planet wheel 3-15 is connected with a second sun wheel 3-14 in a matching manner, a planet wheel II 3-15 is fixedly connected with another planet wheel rotating rod I3-16, the planet wheel rotating rod I3-16 is rotatably connected with the planet wheel II 3-15, the planet wheel II 3-15 is matched and connected with a sun wheel I3-10, the planet wheel rotating rod I3-16 is rotatably connected with a support III 3-4, a forging slide rod II 3-18 is fixedly connected with the planet wheel II 3-15, the forging slide rod II 3-18 is slidably connected with the forging slide rod I3-12, a forging slide rod pushing spring II 3-20 is arranged between the forging slide rod II 3-18 and the forging slide rod I3-12, the forging slide rod II 3-13 is slidably connected with the forging slide rod I3-17, the forging slide rod pushing spring I3-19 is arranged between the forging slide rod II 3-13 and the forging slide rod I3-17, the forging slide bar I3-17 is fixedly connected with the planet wheel II 3-15;

the rotation of the output friction wheel 1-2 drives the movement of the second underframe belt 4-5, which in turn drives the movement of the lower end rotating rod 2-2, which in turn drives the movement of the first underframe belt 4-4 via the lower end rotating rod 2-2, which in turn drives the movement of the first planet wheel rotating rod 3-16 via the first underframe belt 4-4, which in turn drives the movement of the second planet wheel 3-15 via the first planet wheel rotating rod 3-16, which in turn drives the movement of the second sun wheel 3-14, which in turn drives the movement of the first planet wheel 3-11 via the first planet wheel rotating rod 3-16, which in turn drives the movement of the first sun wheel 3-10, which in turn drives the movement of the second planet wheel 3-15 via the first planet wheel rotating rod 3-16 connected with the first sun wheel 3-10, which in turn drives the movement of the second planet wheel 3-15, which in, The planet wheels I3-11, the sun wheels I3-10 and the sun wheels II 3-14 move, and when the planet wheels II 3-15 and the planet wheels I3-11 move, the slide rods I3-17 are respectively forged; the forging slide bar II 3-18 drives the forging slide bar I3-19 to push the spring; forging a second sliding rod push spring 3-20, and further forging the first sliding rod push spring 3-19; a second forging slide rod push spring 3-20 drives a first forging rod 3-12; moving the forging rod II 3-13 downwards, and further moving the forging rod I3-12; and the forging rods 3-13 are contacted with the material, so that the material is forged, and meanwhile, in the process of waiting for forging, the motion relations between the forging rods 3-12 and the forging rods 3-13 are newly and alternately contacted with the material, so that the forging efficiency of the material is conveniently improved.

The fifth concrete implementation mode:

the embodiment is described below with reference to fig. 1-13, and the embodiment further describes the first embodiment, where the underframe assembly 4 includes an underframe body 4-1, an underframe support 4-2, an underframe support two 4-3, an underframe belt 4-4, an underframe belt two 4-5, an underframe support three 4-6, an underframe support one 4-2, an underframe support two 4-3, and an underframe support three 4-6 fixedly connected with the underframe body 4-1, the underframe belt one 4-4 is disposed between the planet wheel rotating rod one 3-16 and the lower end rotating rod 2-2, the underframe belt two 4-5 is disposed between the output friction wheel 1-2 and the lower end rotating rod 2-2, the power bottom plate 1-1 is fixedly connected with the underframe support three 4-6, the N-type frame 2-1 is slidably connected with the underframe body 4-1, the first underframe support 4-2 is fixedly connected with the first support 3-1, and the second underframe support 4-3 is fixedly connected with the fifth support 3-6.

The invention relates to a material forging device for buildings, which has the working principle that:

when in use, the input motor 1-29 is started, the input motor 1-29 drives the straight tooth two 1-28 to rotate, the straight tooth one 1-27 drives the clutch lever slide bar 1-25 to rotate, the clutch lever two 1-24 to move, the clutch lever two 1-24 drives the clutch lever one 1-23 to rotate, the clutch lever one 1-23 drives the swing rotary lever 1-22 to rotate, the rotary lever slide bar three 1-21 to move, the rotary lever slide bar three 1-21 drives the rotary lever slide bar two 1-14 to move, the clamping groove one 1-13 is connected with the inner end clamping lever one 1-16 in a matching way, the sleeve one 1-15 to move, and the sleeve one 1-15 drives the rotary lever slide bar one 1-12 to move, the rotating rod 1-11 is driven to rotate through the matching connection of the clamping groove II 1-18 and the inner end clamping rod II 1-19, the prismatic sliding rod 1-10 is driven to move, the input friction wheel 1-4 is driven to move through the prismatic sliding rod 1-10, the output friction wheel 1-2 is driven to move through the end friction wheel 1-3, power output is performed, the rotating speed output through the output friction wheel 1-2 can be adjusted according to actual conditions, the sliding rod 1-7 is driven to slide along the auxiliary sliding rod 1-5 manually, the transmission position of the input friction wheel 1-4 on the middle end friction wheel 1-3 is changed through driving the sliding rod 1-7, and the distance between the transmission position of the input friction wheel 1-4 on the middle end friction wheel 1-3 and the rotation axis of the middle end friction wheel 1-3 and the distance between the transmission position of the output friction wheel 1-2 on the middle end friction wheel 1-3 are enabled to be matched and connected The ratio of the distance between the transmission position on the wheel 1-3 and the rotation axis of the middle-end friction wheel 1-3 is changed, so that the speed output by the output friction wheel 1-2 is changed; placing the material to be processed on the middle-end bearing rod 2-5, further moving the middle-end bearing rod 2-5 downwards, further driving the hinged fixing rod 2-6 through the middle-end bearing rod 2-5, further enabling the hinged fixing rod 2-6 to simultaneously rotate inwards, further enabling the hinged fixing rod 2-6 to be in contact with the material to be processed, further realizing the fixation of the material to be processed, simultaneously realizing the fixation of the materials with different specifications, manually rotating the manual rotary table 2-3, further enabling the auxiliary sliding rod 2-7 to slide on the fixed rotary table 2-4 through the action of the lower end sliding groove 2-9 on the manual rotary table 2-3 and the auxiliary sliding rod 2-7, further enabling the use position of the auxiliary sliding rod 2-7 on the fixed rotary table 2-4 to be changed, the positions of the hinged columns 2-8 are changed, the hinged fixing rods 2-6 are driven through the hinged columns 2-8, the hinged fixing rods 2-6 are turned over upwards, the distance between the hinged fixing rods 2-6 is changed, and materials of different specifications are fixed; the rotation of the output friction wheel 1-2 drives the movement of the second underframe belt 4-5, which in turn drives the movement of the lower end rotating rod 2-2, which in turn drives the movement of the first underframe belt 4-4 via the lower end rotating rod 2-2, which in turn drives the movement of the first planet wheel rotating rod 3-16 via the first underframe belt 4-4, which in turn drives the movement of the second planet wheel 3-15 via the first planet wheel rotating rod 3-16, which in turn drives the movement of the second sun wheel 3-14, which in turn drives the movement of the first planet wheel 3-11 via the first planet wheel rotating rod 3-16, which in turn drives the movement of the first sun wheel 3-10, which in turn drives the movement of the second planet wheel 3-15 via the first planet wheel rotating rod 3-16 connected with the first sun wheel 3-10, which in turn drives the movement of the second planet wheel 3-15, which in, The planet wheels I3-11, the sun wheels I3-10 and the sun wheels II 3-14 move, and when the planet wheels II 3-15 and the planet wheels I3-11 move, the slide rods I3-17 are respectively forged; the forging slide bar II 3-18 drives the forging slide bar I3-19 to push the spring; forging a second sliding rod push spring 3-20, and further forging the first sliding rod push spring 3-19; a second forging slide rod push spring 3-20 drives a first forging rod 3-12; moving the forging rod II 3-13 downwards, and further moving the forging rod I3-12; and the forging rods 3-13 are contacted with the material, so that the material is forged, and meanwhile, in the process of waiting for forging, the motion relations between the forging rods 3-12 and the forging rods 3-13 are newly and alternately contacted with the material, so that the forging efficiency of the material is conveniently 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

1. The utility model provides a material forging equipment for building, includes power supply assembly (1), fixed assembly (2), forging assembly (3), chassis assembly (4), its characterized in that: the power source assembly (1) is connected with the bottom frame assembly (4), the fixing assembly (2) is connected with the bottom frame assembly (4), and the forging assembly (3) is connected with the bottom frame assembly (4).

2. The building material forging apparatus as recited in claim 1, wherein: the power source assembly (1) comprises a power bottom plate (1-1), an output friction wheel (1-2), a middle-end friction wheel (1-3), an input friction wheel (1-4), an auxiliary sliding rod (1-5), a spherical clamping groove (1-6), a driving sliding rod (1-7), a spherical clamp (1-8), a spherical clamp push spring (1-9), a prismatic sliding rod (1-10), a rotating rod I (1-11), a rotating rod I (1-12), a clamping groove I (1-13), a rotating rod II (1-14), a sleeve I (1-15), an inner-end clamping rod I (1-16), an inner-end clamping rod push spring I (1-17), a clamping groove II (1-18), an inner-end clamping rod II (1-19), and an inner-end clamping rod push spring II (1-20), A rotating rod sliding rod III (1-21), a swinging rotating rod (1-22), a clutch rod I (1-23), a clutch rod II (1-24), a clutch rod sliding rod (1-25), a clutch rod push spring (1-26), a straight tooth I (1-27), a straight tooth II (1-28), an input motor (1-29), a clutch clip (1-30), a hinged rotor (1-31), a rectangular boss (1-32), a middle end rotating column (1-33) and a clip push spring (1-34), a middle end friction wheel (1-3) and an output friction wheel (1-2) are rotationally connected with a power bottom plate (1-1), the output friction wheel (1-2) and the middle end friction wheel (1-3) are in friction transmission, the input friction wheel (1-4) and the middle end friction wheel (1-3) are in friction transmission, an input friction wheel (1-4) is connected with a prismatic sliding rod (1-10) in a sliding manner, the prismatic sliding rod (1-10) is connected with a power bottom plate (1-1) in a rotating manner, an auxiliary sliding rod (1-5) is fixedly connected with the power bottom plate (1-1), a spherical clamping groove (1-6) is arranged on the auxiliary sliding rod (1-5), a driving sliding rod (1-7) is connected with the auxiliary sliding rod (1-5) in a sliding manner, the driving sliding rod (1-7) is connected with the input friction wheel (1-4) in a matching manner, a rotating rod I (1-11) is fixedly connected with the prismatic sliding rod (1-10), a spherical clamp (1-8) is connected with the driving sliding rod (1-7) in a sliding manner, a spherical clamp (1-8) is connected with the spherical clamping groove (1-6) in a matching manner, and a spherical clamp push spring (1-9) is arranged between the spherical clamp (1-8) and 7) an inner end clamping rod II (1-19) is connected with a rotating rod I (1-11) in a sliding way, an inner end clamping rod push spring II (1-20) is arranged between the inner end clamping rod II (1-19) and the rotating rod I (1-11), the inner end clamping rod push spring II (1-20) is connected with the inner end clamping rod II (1-19) in a sleeved way, the inner end clamping rod II (1-19) is connected with a clamping groove II (1-18) in a matched way, the clamping groove II (1-18) is arranged on a rotating rod sliding rod I (1-12), the clamping groove I (1-13) is arranged on the rotating rod sliding rod II (1-14), the rotating rod sliding rod I (1-12) is connected with a sleeve I (1-15) in a rotating way, the inner end clamping rod I (1-16) is connected with the sleeve I (1-15) in a sliding way, and the inner end clamping rod push spring I (1-17) is connected with the inner end clamping rod I (1-16) in a, an inner end clamping rod push spring I (1-17) is arranged between an inner end clamping rod I (1-16) and a sleeve I (1-15), the inner end clamping rod I (1-16) is matched and connected with a clamping groove I (1-13), a rotating rod I (1-11) is hinged with a rotating rod III (1-21), the rotating rod III (1-21) is connected with a swinging rotating rod (1-22) in a sliding way, the swinging rotating rod (1-22) is fixedly connected with a clutch rod I (1-23), the clutch rod I (1-23) is connected with a power bottom plate (1-1) in a rotating way, a middle end rotating column (1-33) is connected with the swinging rotating rod (1-22) in a rotating way, a rectangular boss (1-32) is connected with the middle end rotating column (1-33) in a rotating way, a hinged rotor (1-31) is connected with the middle end rotating column (1-33) in a rotating way, a rotating rod sliding rod III (1-21) is rotationally connected with a hinged rotor (1-31), a clutch clamp (1-30) is in fit connection with a clutch rod I (1-23), the clutch clamp (1-30) is in sliding connection with a clutch rod II (1-24), a clamp push spring (1-34) is arranged between the clutch clamp (1-30) and the clutch rod II (1-24), the clutch rod II (1-24) is in sliding connection with the clutch rod sliding rod (1-25), a clutch rod push spring (1-26) is in sleeve connection with the clutch rod sliding rod (1-25), a clutch rod push spring (1-26) is arranged between the clutch rod II (1-24) and the clutch rod sliding rod (1-25), a straight tooth I (1-27) is fixedly connected with the clutch rod sliding rod (1-25), a straight tooth I (1-27) is engaged with the straight tooth II (1-28), the straight teeth II (1-28) are fixedly connected with the input motor (1-29).

3. The building material forging apparatus as recited in claim 1, wherein: the fixed combination body (2) comprises an N-shaped frame (2-1), a lower end rotating rod (2-2), a manual rotating disc (2-3), a fixed rotating disc (2-4), a middle end bearing rod (2-5), a hinged fixed rod (2-6), an auxiliary sliding rod (2-7), a hinged column (2-8), a lower end sliding groove (2-9), a bevel gear I (2-10), a bevel gear II (2-11), an inner end sliding column (2-12) and an inner end sliding column push spring (2-13), the lower end rotating rod (2-2) is rotatably connected with the N-shaped frame (2-1), the manual rotating disc (2-3) is rotatably connected with the N-shaped frame (2-1), the fixed rotating disc (2-4) is rotatably connected with the manual rotating disc (2-3), the middle end bearing rod (2-5) is slidably connected with the fixed rotating disc (2-4), the hinged fixed rod (2-6) is hinged with the middle-end bearing rod (2-5), the hinged fixed rod (2-6) is connected with the hinged column (2-8) in a sliding fit manner, the hinged column (2-8) is connected with the inner-end sliding column (2-12) in a sliding manner, the inner-end sliding column push spring (2-13) is connected with the inner-end sliding column (2-12) in a sleeved manner, the inner-end sliding column (2-12) is fixedly connected with the auxiliary sliding rod (2-7), the auxiliary sliding rod (2-7) is connected with the fixed turntable (2-4) in a sliding manner, the lower-end sliding chute (2-9) is arranged on the manual turntable (2-3), the auxiliary sliding rod (2-7) is connected with the lower-end sliding chute (2-9) in a sliding fit manner, and the first conical tooth (2-10) is fixedly connected with the fixed turntable, the second bevel gear (2-11) is in meshing transmission with the first bevel gear (2-10), and the second bevel gear (2-11) is fixedly connected with the lower rotating rod (2-2).

4. The building material forging apparatus as recited in claim 1, wherein: the forging combination body (3) comprises a first support (3-1), a second support (3-3), a third support (3-4), a fourth support (3-5), a fifth support (3-6), a rotary support column (3-7), a first limiting sleeve (3-8), a second limiting sleeve (3-9), a first sun wheel (3-10), a first planet wheel (3-11), a first forging rod (3-12), a second forging rod (3-13), a second sun wheel (3-14), a second planet wheel (3-15), a first planet wheel rotary rod (3-16), a first forging rod (3-17), a second forging rod (3-18), a first forging rod push spring (3-19), a second forging rod push spring (3-20) and a second planet wheel rotary rod (3-21), the second support (3-3) is fixedly connected with the first support (3-1), the third support (3-4) is fixedly connected with the second support (3-3), the fifth support (3-6) is fixedly connected with the fourth support (3-5), the support rotary column (3-7) and the fifth support (3-6) are fixedly connected with the second support (3-3), the first limit sleeve (3-8) and the second limit sleeve (3-9) are rotatably connected with the support rotary column (3-7), the first forging rod (3-12) and the second forging rod (3-13) are respectively connected with the first limit sleeve (3-8) and the second limit sleeve (3-9) in a matching manner, the first sun wheel (3-10) is fixedly connected with the second planet wheel rotary rod (3-21), and the second planet wheel rotary rod (3-21) is rotatably connected with the third support (3-4), a planet wheel rotating rod II (3-21) is rotatably connected with a planet wheel II (3-15), the planet wheel II (3-15) is in fit connection with a sun wheel II (3-14), the planet wheel II (3-15) is fixedly connected with another planet wheel rotating rod I (3-16), the planet wheel rotating rod I (3-16) is rotatably connected with the planet wheel II (3-15), the planet wheel II (3-15) is in fit connection with a sun wheel I (3-10), the planet wheel rotating rod I (3-16) is rotatably connected with a bracket III (3-4), a forging sliding rod II (3-18) is fixedly connected with the planet wheel II (3-15), the forging sliding rod II (3-18) is slidably connected with a forging rod I (3-12), and a forging sliding rod pushing spring II (3-20) is arranged between the forging sliding rod II (3-18) and the forging rod I (3-12), the forging rod II (3-13) is connected with the forging slide rod I (3-17) in a sliding mode, the forging slide rod push spring I (3-19) is arranged between the forging rod II (3-13) and the forging slide rod I (3-17), and the forging slide rod I (3-17) is fixedly connected with the planet wheel II (3-15).

5. The building material forging apparatus as recited in claim 1, wherein: the underframe assembly (4) comprises an underframe body (4-1), an underframe bracket I (4-2), an underframe bracket II (4-3), an underframe belt I (4-4), an underframe belt II (4-5) and an underframe bracket III (4-6), wherein the underframe bracket I (4-2), the underframe bracket II (4-3) and the underframe bracket III (4-6) are fixedly connected with the underframe body (4-1), the underframe belt I (4-4) is arranged between a planet wheel rotating rod I (3-16) and a lower end rotating rod (2-2), the underframe belt II (4-5) is arranged between an output friction wheel (1-2) and the lower end rotating rod (2-2), a power bottom plate (1-1) is fixedly connected with the underframe bracket III (4-6), the N-shaped frame (2-1) is connected with the underframe body (4-1) in a sliding mode, the underframe bracket I (4-2) is fixedly connected with the bracket I (3-1), and the underframe bracket II (4-3) is fixedly connected with the bracket V (3-6).