CN220805425U - Hydraulic tank Liang Gangmo structure - Google Patents

Abstract

The utility model relates to the technical field of hydraulic box girder steel mould pouring, in particular to a hydraulic box girder steel mould structure, which comprises: the casting mold comprises a cast-in-situ box, wherein one side of the cast-in-situ box is provided with two molds, one side of each mold is provided with a pouring opening, and a vibration pouring mechanism is arranged on one side of the cast-in-situ box and used for improving the molding quality of the steel template of the box girder, and comprises a vibration assembly arranged in the cast-in-situ box; the box girder steel template can be cast-in-situ through the cast-in-situ box and the two moulds, when the box girder steel template is formed, the two moulds can be vibrated through the vibration component, the vibration is conducted to the inside of the two moulds, and air bubbles in the unground box girder steel template can be effectively discharged, so that the forming quality of the box girder steel template is improved, and when the box girder steel template is poured, the two moulds can be conveniently closed and opened through the driving component.

Description

Hydraulic tank Liang Gangmo structure

Technical Field

The utility model relates to the technical field of hydraulic box girder steel mould pouring, in particular to a hydraulic box girder steel mould structure.

Background

The hydraulic box girder steel template is one of the girders in the hydraulic box girder bridge engineering, the inside is hollow, flanges are arranged on two sides of the upper part, and the hydraulic box girder steel template is similar to a box, thus the name is obtained, and the hydraulic box girder steel template is divided into single boxes, multiple boxes and the like;

when the cast-in-situ box girder steel template is formed on site, if bubbles remain in the cast-in-situ box girder steel template, the quality and the use effect of the hydraulic box girder steel template can be affected.

Accordingly, a hydraulic tank Liang Gangmo structure is proposed to solve the above-mentioned problems.

Disclosure of utility model

The utility model aims to solve the problems, and provides a hydraulic box Liang Gangmo structure, which solves the problems that when a cast-in-situ box girder steel template is formed on site, if bubbles remain in the cast-in-situ box girder steel template, the quality and the use effect of the hydraulic box girder steel template are affected.

The utility model realizes the above purpose through the following technical scheme, a hydraulic tank Liang Gangmo structure, comprising: the cast-in-place case, one side of cast-in-place case is provided with two moulds, and one side of two moulds all is provided with the pouring mouth, shakes and pours the mechanism for carry out the promotion to the shaping quality of case girder steel form vibrations pouring the mechanism and set up in one side of cast-in-place case, wherein, shake and pour the mechanism including setting up in the inside vibrations subassembly of cast-in-place case, shake and pour the mechanism and still including setting up in the drive assembly of two moulds one side, shake the subassembly including slidable mounting in the inside fly leaf of cast-in-place case, the fly leaf is located two the below of mould can cast-in-place case girder steel form with two moulds, can vibrate two moulds through vibrations subassembly when case girder steel form is fashioned, vibrations conduction to two moulds are inside, can effectually with the inside bubble of unformed case girder steel form to promote the shaping quality of case girder steel form, and when pouring case girder steel form, can be convenient through drive assembly to close and open two moulds.

Preferably, the vibration assembly further comprises a motor fixedly arranged on the inner bottom wall of the cast-in-situ box, two driving rods are rotatably arranged in the cast-in-situ box, one side of each driving rod is fixedly connected with the output end of the motor, the surfaces of the two driving rods are fixedly connected with driving wheels, a plurality of grooves are formed in the surfaces of the driving wheels, two contact blocks are fixedly connected with the bottom of the movable plate, the driving wheels are respectively positioned below the two contact blocks, the contact blocks are contacted with the adjacent grooves, the grooves are matched with the shape of the contact blocks, the corresponding driving rods can synchronously drive the driving wheels through the motor during vibration, the driving wheels are continuously contacted with the contact blocks at the bottom of the movable plate through the grooves during rotation, the contact blocks can be continuously jacked up, the movable plate can continuously move up and down, the two dies can continuously collide, the two inner unshaped box girder steel templates vibrate, and therefore, internal bubbles are discharged, and the molding quality of the box girder steel templates is improved.

Preferably, the vibration assembly further comprises a plurality of supporting rods fixedly installed at the bottom of the movable plate, the outer sides of the supporting rods are respectively sleeved with a branch pipe in a sliding mode, the bottom ends of the branch pipes are respectively fixedly connected with the inner bottom wall of the cast-in-situ box, the bottoms of the supporting rods are fixedly connected with first springs, the other ends of the first springs are respectively fixedly connected with the inner wall of the cast-in-situ box, when the movable plate is impacted by the driving wheel, the vibration frequency of the movable plate can be increased through the supporting rods and the corresponding first springs, and therefore the impact frequency of the movable plate on two molds is improved.

Preferably, the surfaces of the two driving rods are fixedly connected with belt pulleys, the two belt pulleys are connected through belt transmission, and the two driving rods can synchronously rotate through the belt pulleys, so that the two driving wheels can synchronously move, and the belt pulleys are quite convenient and fast.

Preferably, the surface of fly leaf has seted up first movable slot, one side sliding connection of first movable slot has two movable plates, two the movable plate is located two respectively one side of mould, two the equal fixedly connected with of adjacent one side of movable plate a plurality of first striking pieces, two the mould is close to one side of movable plate a plurality of second striking pieces of equal fixedly connected with, a plurality of first striking pieces and the mutual crisscross setting of second striking piece of homonymy, two the inside fixedly connected with of first movable slot two second springs, two the other end of second spring respectively with two movable plate fixed connection can drive two movable plates simultaneously when the movable plate reciprocates, can be through first striking piece continuous with adjacent second striking piece striking when two movable plates move for two movable plates can be continuous bump outside two moulds, promote the exhaust bubble to inside unshaped case roof beam board from this, can make the movable plate continuous deformation through second striking piece and second spring and make the second movable plate drive the second bump piece again when every second striking piece moves.

Preferably, two heaters are arranged in the cast-in-situ box, the two heaters are respectively positioned at one sides of the two dies, and certain heat can be provided by the two heaters when the box girder steel template is formed, so that the forming speed of the box girder steel template is accelerated, and the efficiency of pouring the box girder steel template is improved.

Preferably, the driving assembly comprises two hydraulic cylinders fixedly mounted on one side of the cast-in-situ box, the two hydraulic cylinders are respectively located on one side of the two dies, the output ends of the two hydraulic cylinders are fixedly connected with the adjacent dies, a second movable groove is formed in the surface of the cast-in-situ box, the two dies are slidably connected with the second movable groove, and the two dies can be conveniently driven to be opened and closed through the two hydraulic cylinders, so that the two dies are more convenient and faster to use.

Preferably, two equal fixedly connected with shielding plate of one side of mould, two the shielding plate all is located the top of second movable groove to after two moulds are closed each other, two shielding plates all can shelter from the second movable groove, can reduce the steam loss of internal heater.

The beneficial effects of the utility model are as follows:

1. The box girder steel template can be cast-in-situ through the cast-in-situ box and the two moulds, when the box girder steel template is formed, the two moulds can be vibrated through the vibration component, the vibration is conducted into the two moulds, and air bubbles in the unshaped box girder steel template can be effectively discharged, so that the forming quality of the box girder steel template is improved, and when the box girder steel template is cast, the two moulds can be conveniently closed and opened through the driving component;

2. Can provide certain heat through two heaters when the shaping of case roof beam steel form to accelerate the shaping speed of case roof beam steel form, promote the efficiency of pouring case roof beam steel form, and after two moulds are closed each other, two shielding plates all can shelter from the second movable groove, can reduce the steam loss of internal heater.

Drawings

FIG. 1 is a schematic diagram of the main structure of the present utility model;

FIG. 2 is a schematic view of the internal structure of the cast-in-situ box according to the present utility model;

FIG. 3 is a schematic view of a vibration assembly according to the present utility model;

Fig. 4 is a schematic view of the structure of the moving plate and the first movable groove of the present utility model.

In the figure: 1. a cast-in-place box; 101. a mold; 102. pouring the port; 103. a heater; 2. a vibration assembly; 201. a movable plate; 202. a branch pipe; 203. a support rod; 204. a first spring; 205. a motor; 206. a driving rod; 207. a driving wheel; 208. a contact block; 209. a belt pulley; 210. a first movable groove; 211. a moving plate; 212. a first impact block; 213. a second spring; 214. a second impact block; 3. a drive assembly; 301. a hydraulic cylinder; 302. a second movable groove; 303. a shielding plate.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

The specific implementation method comprises the following steps: as shown in fig. 1-4, a hydraulic box girder steel mold structure includes: the box casting machine comprises a cast-in-situ box 1, two dies 101 are arranged on one side of the cast-in-situ box 1, casting ports 102 are formed on one side of the two dies 101, a vibration casting mechanism is arranged on one side of the cast-in-situ box 1 and used for improving the molding quality of the box girder steel template, the vibration casting mechanism comprises a vibration assembly 2 arranged in the cast-in-situ box 1, the vibration casting mechanism further comprises a driving assembly 3 arranged on one side of the two dies 101, the vibration assembly 2 comprises a movable plate 201 which is slidably arranged in the cast-in-situ box 1, the movable plate 201 is positioned below the two dies 101, the box girder steel template can be cast-in-situ through the cast-in-situ box 1 and the two dies 101, when the box girder steel template is molded, the two dies 101 can be vibrated through the vibration assembly 2, air bubbles in the non-molded box girder steel template can be effectively discharged, so that the molding quality of the box girder steel template is improved, and when the box girder steel template is cast, the two dies 101 can be conveniently closed and opened through the driving assembly 3.

As shown in fig. 2-4, the vibration assembly 2 further comprises a motor 205 fixedly installed at the inner bottom wall of the cast-in-situ box 1, two driving rods 206 are rotatably installed inside the cast-in-situ box 1, one side of the driving rod 206 is fixedly connected with the output end of the motor 205, the surfaces of the two driving rods 206 are fixedly connected with driving wheels 207, a plurality of grooves are formed on the surfaces of the driving wheels 207, two contact blocks 208 are fixedly connected with the bottom of the movable plate 201, the two driving wheels 207 are respectively positioned below the two contact blocks 208, the contact blocks 208 are contacted with adjacent grooves, the grooves are matched with the contact blocks 208 in shape, the corresponding driving rods 206 can synchronously drive the driving wheels 207 to rotate through the motor 205 during vibration, the driving wheels 207 can continuously contact the contact blocks 208 at the bottom of the movable plate 201 through the grooves during rotation, the movable plate 201 can be continuously jacked up and down, the two moulds 101 are impacted continuously, so that the formed box girder steel templates in the two moulds 101 vibrate, internal bubbles are discharged, the forming quality of the box girder steel templates is improved, the vibration assembly 2 further comprises a plurality of supporting rods 203 fixedly arranged at the bottom of the movable plate 201, the outer sides of the supporting rods 203 are respectively sleeved with a supporting pipe 202 in a sliding manner, the bottom ends of the supporting rods 202 are respectively fixedly connected with the inner bottom wall of the cast-in-situ box 1, the bottom of the supporting rods 203 is fixedly connected with a first spring 204, the other ends of the first springs 204 are respectively fixedly connected with the inner wall of the cast-in-situ box 1, when the movable plate 201 is impacted continuously by the driving wheels 207, the vibration frequency of the movable plate 201 can be increased through the supporting rods 203 and the corresponding first springs 204, so that the impact frequency of the movable plate 201 to the two moulds 101 is improved, the surfaces of the two driving rods 206 are respectively fixedly connected with belt pulleys 209, the two belt pulleys 209 are connected through belt transmission, the two driving rods 206 can synchronously rotate through the belt pulley 209, so that the two driving wheels 207 can synchronously move, and the device is quite convenient;

The surface of the movable plate 201 is provided with a first movable groove 210, one side of the first movable groove 210 is connected with two movable plates 211 in a sliding way, the two movable plates 211 are respectively positioned on one side of the two dies 101, one side adjacent to the two movable plates 211 is fixedly connected with a plurality of first impact blocks 212, one side, close to the movable plates 211, of the two dies 101 is fixedly connected with a plurality of second impact blocks 214, the first impact blocks 212 and the second impact blocks 214 on the same side are arranged in a staggered way, the inside of the first movable groove 210 is fixedly connected with two second springs 213, the other ends of the two second springs 213 are respectively fixedly connected with the two movable plates 211, when the movable plate 201 moves up and down, the two movable plates 211 can be synchronously driven to move up and down, and when the two movable plates 211 move, the two movable plates can be continuously impacted with the adjacent second impact blocks 214 through the first impact blocks 212, so that two movable plates 211 can be constantly strike two moulds 101 outsides when movable plate 201 moves, promote the bubble effect of exhausting to inside unformed case roof beam steel form from this, when movable plate 211 and second striking piece 214 strike at every turn and remove, second spring 213 produces deformation, can constantly reset movable plate 211 through second spring 213, make movable plate 211 can continuously drive first striking piece 212 striking adjacent second striking piece 214, cast-in-place case 1's inside is provided with two heaters 103, two heaters 103 are located one side of two moulds 101 respectively, can provide certain heat when case roof beam steel form shaping through two heaters 103, thereby accelerate the shaping speed of case roof beam steel form, promote the efficiency of pouring case roof beam steel form.

As shown in fig. 2-4, the driving assembly 3 includes two hydraulic cylinders 301 fixedly installed at one side of the cast-in-situ box 1, the two hydraulic cylinders 301 are respectively located at one side of the two dies 101, output ends of the two hydraulic cylinders 301 are fixedly connected with the adjacent dies 101, a second movable groove 302 is formed in the surface of the cast-in-situ box 1, the two dies 101 are slidably connected with the second movable groove 302, the two dies 101 can be conveniently driven to be opened and closed by the two hydraulic cylinders 301, so that the two dies 101 are more convenient and faster in use, a shielding plate 303 is fixedly connected to one side of each of the two dies 101, the two shielding plates 303 are located above the second movable groove 302, and after the two dies 101 are mutually closed, the two shielding plates 303 can shield the second movable groove 302, and loss of hot air of the internal heater 103 can be reduced.

When the utility model is used, the corresponding driving rod 206 can synchronously drive the driving wheel 207 to rotate through the motor 205 during vibration, the driving wheel 207 continuously contacts with the contact block 208 at the bottom of the movable plate 201 through the groove during rotation, the contact block 208 can be continuously jacked up, the movable plate 201 can continuously move up and down, the two dies 101 are continuously impacted, the inside of the two dies 101 is formed into the vibration of the box girder steel moulding plate, the internal air bubble is discharged, the forming quality of the box girder steel moulding plate is improved, when the movable plate 201 is continuously impacted by the driving wheel 207, the vibration frequency of the movable plate 201 can be increased through the supporting rod 203 and the corresponding first spring 204, the impact frequency of the movable plate 201 to the two dies 101 can be improved, the two driving rods 206 can synchronously rotate through the belt pulley 209, the two driving wheels 207 can also synchronously move, and the utility model is very convenient, when the movable plate 201 moves up and down, the two movable plates 211 can be synchronously driven to move up and down, when the two movable plates 211 move, the two movable plates 211 can continuously collide with the adjacent second collision blocks 214 through the first collision blocks 212, so that when the movable plate 201 moves, the two movable plates 211 can continuously collide with the outer sides of the two dies 101, thereby improving the air bubble effect on the inside unshaped box girder steel template, when the movable plates 211 and the second collision blocks 214 each time collide and move, the second springs 213 deform, the movable plates 211 can be continuously reset through the second springs 213, the movable plates 211 can continuously drive the first collision blocks 212 to collide with the adjacent second collision blocks 214, a certain amount of heat can be provided by the two heating machines 103 when the box girder steel template is formed, the forming speed of the box girder steel template is accelerated, the efficiency of pouring the box girder steel template is improved, and after the two dies 101 are mutually closed, the two shielding plates 303 can shield the second movable groove 302, so that the heat loss of the internal heater 103 can be reduced.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (8)

1. A hydraulic tank Liang Gangmo structure, comprising:

the casting device comprises a cast-in-situ box (1), wherein two molds (101) are arranged on one side of the cast-in-situ box (1), and casting ports (102) are formed on one side of each of the two molds (101);

The vibration pouring mechanism is used for improving the molding quality of the steel template of the box girder and is arranged at one side of the cast-in-situ box (1);

The vibration pouring mechanism comprises a vibration assembly (2) arranged in the cast-in-situ box (1), and further comprises a driving assembly (3) arranged at one side of the two dies (101);

The vibration assembly (2) comprises a movable plate (201) which is slidably arranged in the cast-in-situ box (1), and the movable plate (201) is positioned below the two dies (101).

2. A hydraulic tank Liang Gangmo as defined in claim 1, wherein: the vibration assembly (2) further comprises a motor (205) fixedly arranged on the inner bottom wall of the cast-in-situ box (1), two driving rods (206) are rotatably arranged in the cast-in-situ box (1), one side of each driving rod is fixedly connected with the output end of the motor (205), the surfaces of the two driving rods (206) are fixedly connected with driving wheels (207), a plurality of grooves are formed in the surfaces of the driving wheels (207), two contact blocks (208) are fixedly connected to the bottom of the movable plate (201), the two driving wheels (207) are respectively arranged below the two contact blocks (208), the contact blocks (208) are in contact with adjacent grooves, and the grooves are matched with the contact blocks (208) in shape.

3. A hydraulic tank Liang Gangmo as defined in claim 1, wherein: the vibration assembly (2) further comprises a plurality of supporting rods (203) fixedly arranged at the bottom of the movable plate (201), a plurality of supporting rods (202) are sleeved on the outer sides of the supporting rods (203) in a sliding mode, the bottom ends of the supporting rods (202) are fixedly connected with the inner bottom wall of the cast-in-situ box (1), a first spring (204) is fixedly connected with the bottom of the supporting rods (203), and the other ends of the first springs (204) are fixedly connected with the inner wall of the cast-in-situ box (1).

4. A hydraulic tank Liang Gangmo as defined in claim 2, wherein: the surfaces of the two driving rods (206) are fixedly connected with belt pulleys (209), and the two belt pulleys (209) are connected through belt transmission.

5. A hydraulic tank Liang Gangmo as defined in claim 1, wherein: first movable groove (210) has been seted up on the surface of fly leaf (201), one side sliding connection of first movable groove (210) has two fly leaves (211), two fly leaves (211) are located two respectively one side of mould (101), two the adjacent one side of fly leaves (211) all fixedly connected with a plurality of first striking piece (212), two the one side that mould (101) is close to fly leaves (211) all fixedly connected with a plurality of second striking piece (214), a plurality of first striking piece (212) and second striking piece (214) of homonymy are crisscross setting each other, two inside fixedly connected with of first movable groove (210) second spring (213), two the other end of second spring (213) respectively with two fly leaves (211) fixed connection.

6. A hydraulic tank Liang Gangmo as defined in claim 1, wherein: two heaters (103) are arranged in the cast-in-situ box (1), and the two heaters (103) are respectively positioned at one sides of the two dies (101).

7. A hydraulic tank Liang Gangmo as defined in claim 1, wherein: the driving assembly (3) comprises two hydraulic cylinders (301) fixedly arranged on one side of the cast-in-situ box (1), the two hydraulic cylinders (301) are respectively positioned on one side of the two dies (101), the output ends of the two hydraulic cylinders (301) are fixedly connected with the adjacent dies (101), a second movable groove (302) is formed in the surface of the cast-in-situ box (1), and the two dies (101) are in sliding connection with the second movable groove (302).

8. A hydraulic tank Liang Gangmo as defined in claim 1, wherein: one side of each of the two dies (101) is fixedly connected with a shielding plate (303), and the two shielding plates (303) are located above the second movable groove (302).