CN221122967U - Dissolution furnace for block casting - Google Patents

Abstract

The utility model relates to the field of dissolution furnaces and discloses a dissolution furnace for block pouring, which solves the problems that the pouring efficiency is reduced when the discharge port of the dissolution furnace is too small compared with the feed port of a die because the sizes of inlets of different dies are different, and the pouring efficiency is wasted when the discharge port of the dissolution furnace is too large compared with the feed port of the die.

Description

Dissolution furnace for block casting

Technical Field

The utility model relates to the field of dissolving furnaces, in particular to a dissolving furnace for block casting.

Background

The block pouring dissolution furnace is a dissolution furnace in which pouring materials are poured into different moulds, and cracks are normal in the use process after pouring the pouring materials, so that the large-area pouring is required to be made into small blocks for controlling the cracks.

When the existing dissolution furnace for block pouring is used for pouring, the sizes of inlets of different dies are different, but the discharge port of the dissolution furnace is fixed, when the discharge port of the dissolution furnace is too small compared with the feed port of the die, the pouring efficiency is reduced, and when the discharge port of the dissolution furnace is too large compared with the feed port of the die, the problem that the dissolution material is poured outside the die and wastes is caused.

Disclosure of utility model

The utility model aims to provide a dissolution furnace for block pouring, which adopts the device to work, so that the problems that the pouring efficiency is slow when the discharge port of the dissolution furnace is too small compared with the feed port of a die and the waste is caused when the dissolution material is poured outside the die because the inlet sizes of different dies are different and the discharge port of the dissolution furnace is fixed are solved.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a dissolution furnace of piecemeal pouring, includes the dissolution furnace main part, sets up the support frame in dissolution furnace main part both sides, sets up the motor in the support frame outside, sets up the transmission shaft at the motor output, sets up the discharge gate in dissolution furnace main part top, sets up the sealed lid in the discharge gate inboard, and the right side of sealed lid is provided with slide mechanism, and slide mechanism's below is provided with screw mechanism;

The sliding mechanism comprises a first connecting plate arranged on the right side of the sealing cover, a first connecting rod is arranged above the first connecting plate, a second connecting plate is arranged above the first connecting rod, a first sliding groove is formed in the second connecting plate, and a second sliding groove is communicated below the first sliding groove.

Preferably, the sealing cover is connected with the dissolving furnace main body in a sliding manner, and the sealing cover is fixedly connected with the first connecting plate.

Preferably, the appearance structure of the second connecting plate is arc-shaped, and the second connecting plate is fixedly connected with the supporting frame.

Preferably, the width of the first chute is consistent with the width of the first connecting rod, and the first connecting rod is fixedly connected with the first connecting plate.

Preferably, the front side surface of the second chute is inclined, and the rear side surface of the second chute is inclined.

Preferably, the inside of support frame is provided with first recess, and screw mechanism is including setting up the baffle in first recess inside, and the right side of baffle is provided with the threaded rod, and the inside second recess that is provided with in left side of baffle, the front side of second spout are provided with the third spout, and the inside third recess that is provided with in right side of baffle, and the left side intercommunication of third recess has the fourth recess, and the inside of fourth recess is provided with the rotary disk.

Preferably, the connection mode of the threaded rod and the support frame is threaded connection, the connection mode of the threaded rod and the rotating disc is fixed connection, and the width of the rotating disc is consistent with the width of the third groove.

Preferably, the third sliding grooves are equidistantly distributed on the front side of the second sliding groove, and the width of the third sliding groove is consistent with that of the first connecting rod.

Preferably, the width of the second groove is consistent with the width of the first connecting rod, and the inclination angle of the second groove is consistent with the inclination angle of the third chute.

Preferably, the width of the first groove is consistent with the width of the baffle, and the appearance structure of the baffle is rectangular.

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

1. According to the block pouring dissolving furnace, the sliding mechanism is arranged, when the dissolving furnace is started to overturn and topple, the sliding mechanism is driven to rotate, and the discharge hole of the dissolving furnace is opened, so that compared with the prior art, the purpose of safer working is achieved without manually opening the discharge hole of the dissolving furnace.

2. According to the dissolving furnace for block pouring, provided by the utility model, the threaded mechanism is arranged, and before the sliding mechanism rotates, the threaded mechanism is rotated, so that the opening degree of the discharge hole of the dissolving furnace is changed, and compared with the prior art, the size of the discharge hole can be set according to the size of the feed hole of the die, thereby achieving the purposes of preventing waste and influencing the dumping efficiency.

Drawings

FIG. 1 is a schematic overall perspective view of the present utility model;

FIG. 2 is a schematic diagram of a sliding mechanism and a screw mechanism according to the present utility model;

FIG. 3 is a schematic view of a baffle plate according to the present utility model;

FIG. 4 is a schematic view of a baffle plate in perspective cut-away;

fig. 5 is a schematic diagram of the structure a in fig. 1 according to the present utility model.

In the figure: 1.a dissolution furnace main body; 2. a support frame; 3. a motor; 4. a transmission shaft; 5. a discharge port; 6. sealing cover; 7. a sliding mechanism; 8. a screw mechanism; 701. a first connection plate; 702. a first connecting rod; 703. a second connecting plate; 704. a first chute; 705. a second chute; 9. a first groove; 801. a baffle; 802. a threaded rod; 803. a second groove; 804. a third chute; 805. a third groove; 806. a fourth groove; 807. and (5) rotating the disc.

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.

Referring to fig. 1-5, the present utility model provides the following technical solutions: the utility model provides a dissolution furnace of piecemeal pouring, includes dissolution furnace main part 1, sets up support frame 2 in dissolution furnace main part 1 both sides, sets up motor 3 in the support frame 2 outside, sets up the transmission shaft 4 of motor 3 output, sets up discharge gate 5 in dissolution furnace main part 1 top, sets up the sealed lid 6 in discharge gate 5 inboard, and the right side of sealed lid 6 is provided with slide mechanism 7, and slide mechanism 7's below is provided with screw mechanism 8;

the sliding mechanism 7 comprises a first connecting plate 701 arranged on the right side of the sealing cover 6, a first connecting rod 702 is arranged above the first connecting plate 701, a second connecting plate 703 is arranged above the first connecting rod 702, a first sliding groove 704 is arranged inside the second connecting plate 703, and a second sliding groove 705 is communicated below the first sliding groove 704.

The sealing cover 6 is connected with the dissolution furnace main body 1 in a sliding manner, and the sealing cover 6 is fixedly connected with the first connecting plate 701.

The appearance structure of the second connecting plate 703 is arc-shaped, and the connection mode of the second connecting plate 703 and the support frame 2 is fixed connection.

The width of the first chute 704 is consistent with the width of the first connecting rod 702, and the connecting mode of the first connecting rod 702 and the first connecting plate 701 is a fixed connection.

The front side surface of the second chute 705 is inclined, and the rear side surface of the second chute 705 is inclined.

The inside of support frame 2 is provided with first recess 9, and screw mechanism 8 is provided with threaded rod 802 including setting up the baffle 801 in the inside of first recess 9, and the right side of baffle 801 is provided with second recess 803 in the inside left side of baffle 801, and the front side of second spout 705 is provided with third spout 804, and the inside third recess 805 that is provided with in the right side of baffle 801, and the left side intercommunication of third recess 805 has fourth recess 806, and the inside of fourth recess 806 is provided with rotary disk 807.

The threaded rod 802 is connected with the support frame 2 in a threaded manner, the threaded rod 802 is fixedly connected with the rotary disk 807, and the width of the rotary disk 807 is consistent with the width of the third groove 805.

The third sliding grooves 804 are equidistantly distributed on the front side of the second sliding groove 705, and the width of the third sliding groove 804 is consistent with the width of the first connecting rod 702.

The width of the second groove 803 is consistent with the width of the first connecting rod 702, and the inclination angle of the second groove 803 is consistent with the inclination angle of the third sliding groove 804.

The width of the first groove 9 is identical to the width of the barrier 801, and the external structural shape of the barrier 801 is rectangular.

The motor 3 is started to drive the transmission shaft 4 to rotate, and then the dissolution furnace main body 1 is driven to rotate, the sealing cover 6 and the first connecting plate 701 are driven to rotate, the first connecting plate 702 is driven to rotate, the width of the first sliding groove 704 is consistent with that of the first connecting plate 702, the first connecting plate 702 is fixedly connected with the first connecting plate 701, the front side surface of the second sliding groove 705 is inclined, the rear side surface of the second sliding groove 705 is inclined, the sealing cover 6 is in sliding connection with the dissolution furnace main body 1, the sealing cover 6 is fixedly connected with the first connecting plate 701, the first connecting plate 702 moves along the first sliding groove 704, when the first connecting plate 702 moves to the position of the second sliding groove 705, the first connecting plate 701 and the sealing cover 6 move to the right side along the oblique side of the second sliding groove 705, the discharge outlet 5 is opened, when the dissolution furnace main body 1 is returned, the first connecting plate 702 moves to the inside of the first sliding groove 705, the discharge outlet 5 is closed along the track of the second sliding groove 705, and the purpose of safely discharging the dissolution furnace is achieved without the need of opening the prior art.

When the first connecting rod 702 rotates to the front side, through rotating the threaded rod 802, because the connection mode of the threaded rod 802 and the support frame 2 is threaded connection, and the connection mode of the threaded rod 802 and the rotating disk 807 is fixed connection, and the width of the rotating disk 807 is consistent with the width of the third groove 805, the width of the first groove 9 is consistent with the width of the baffle 801, and the appearance structure shape of the baffle 801 is rectangular, so that the rotating threaded rod 802 drives the baffle 801 to move, the third groove 804 is equidistantly distributed on the front side of the second groove 705, and the width of the third groove 804 is consistent with the width of the first groove 702, the width of the second groove 803 is consistent with the width of the first groove 702, and the inclination angle of the second groove 803 is consistent with the inclination angle of the third groove 804, so that the first groove 702 can move to the inside of the third groove 804 along the track of the second groove 803, and the first groove 702 can be pulled to the right side by different distances, and the opening degree of the discharge port 5 is different, and compared with the prior art, the size of the discharge port 5 can be set according to the size of the die material inlet, thereby preventing waste and efficiency from being caused.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (10)

1. The utility model provides a dissolution furnace of piecemeal pouring, including dissolution furnace main part (1), support frame (2) of setting in dissolution furnace main part (1) both sides, set up motor (3) in the support frame (2) outside, set up transmission shaft (4) at motor (3) output, set up discharge gate (5) and sealed lid (6) of setting inboard in discharge gate (5) in dissolution furnace main part (1), its characterized in that: a sliding mechanism (7) is arranged on the right side of the sealing cover (6), and a thread mechanism (8) is arranged below the sliding mechanism (7);

The sliding mechanism (7) comprises a first connecting plate (701) arranged on the right side of the sealing cover (6), a first connecting rod (702) is arranged above the first connecting plate (701), a second connecting plate (703) is arranged above the first connecting rod (702), a first sliding groove (704) is formed in the second connecting plate (703), and a second sliding groove (705) is formed in the lower portion of the first sliding groove (704) in communication.

2. The block poured dissolution furnace of claim 1, wherein: the sealing cover (6) is connected with the dissolution furnace main body (1) in a sliding mode, and the sealing cover (6) is fixedly connected with the first connecting plate (701).

3. The block poured dissolution furnace of claim 1, wherein: the appearance structure of the second connecting plate (703) is arc-shaped, and the second connecting plate (703) is fixedly connected with the support frame (2).

4. The block poured dissolution furnace of claim 1, wherein: the width of the first sliding groove (704) is consistent with that of the first connecting rod (702), and the first connecting rod (702) is fixedly connected with the first connecting plate (701).

5. The block poured dissolution furnace of claim 1, wherein: the front side surface of the second chute (705) is inclined, and the rear side surface of the second chute (705) is inclined.

6. The block poured dissolution furnace of claim 1, wherein: the inside of support frame (2) is provided with first recess (9), screw mechanism (8) are including setting up baffle (801) inside first recess (9), the right side of baffle (801) is provided with threaded rod (802), the inside second recess (803) that is provided with in left side of baffle (801), the front side of second spout (705) is provided with third spout (804), the inside third recess (805) that is provided with in right side of baffle (801), the left side intercommunication of third recess (805) has fourth recess (806), the inside rotary disk (807) that is provided with of fourth recess (806).

7. The block poured dissolution furnace of claim 6, wherein: the threaded rod (802) is in threaded connection with the support frame (2), the threaded rod (802) is in fixed connection with the rotating disc (807), and the width of the rotating disc (807) is consistent with the width of the third groove (805).

8. The block poured dissolution furnace of claim 6, wherein: the third sliding grooves (804) are equidistantly distributed on the front side of the second sliding groove (705), and the width of the third sliding groove (804) is consistent with that of the first connecting rod (702).

9. The block poured dissolution furnace of claim 6, wherein: the width of the second groove (803) is consistent with the width of the first connecting rod (702), and the inclination angle of the second groove (803) is consistent with the inclination angle of the third chute (804).

10. The block poured dissolution furnace of claim 6, wherein: the width of the first groove (9) is consistent with the width of the baffle plate (801), and the appearance structure shape of the baffle plate (801) is rectangular.