CN109132487B - Chemical reaction jar material feeding unit - Google Patents

Abstract

The invention discloses a chemical reaction tank feeding device, which comprises a support 8 arranged above a reaction tank 7, wherein a material barrel 9 for containing materials is arranged on the support 8, the support 8 is connected with a cross rod 10 below the material barrel 9 in a sliding manner, one end of the cross rod 10, which faces to the material barrel 9, is rotatably connected with a swinging plate 11, and the swinging plate 11 is connected with the cross rod 10 through a butting device; a cavity 12 used for containing materials falling from the charging barrel 9 is formed in one side, facing the charging barrel 9, of the swinging plate 11, a first vertical plate 5 and a second vertical plate 6 which are used for being tightly abutted or separated from the upper end of the swinging plate 11 in sequence are arranged on the support 8, and the first vertical plate 5 and the second vertical plate 6 are respectively located on two sides of the upper end of the swinging plate 11; the two sides of the cavity 12 are respectively provided with a first baffle plate 1 and a second baffle plate 2 which are parallel to each other, and a rotating shaft between the cross rod 10 and the swinging plate 11 is positioned between the first baffle plate 1 and the second baffle plate 2. The chemical reaction tank feeding device can automatically feed materials and is safer and more reliable in feeding process.

Description

Chemical reaction jar material feeding unit

Technical Field

The invention relates to a feeding device of a chemical reaction tank.

Background

The chemical reaction tank is a container for containing chemical substances to perform chemical reaction, in the actual chemical reaction process, an operator can put the chemical substances needing to participate in the reaction into the container according to the time sequence, and the container is widely applied to the technical processes of petroleum, chemical industry, rubber, medicines, pesticides and the like. The material feeding mode in the prior art is to manually feed materials to be added into a reaction tank into the reaction tank, an opening is formed in the upper part of a general reaction tank for feeding the materials, the materials can release toxic and harmful gases from the opening at the upper end when the materials are subjected to chemical reaction in the reaction tank, or liquid can splash from the opening at the upper end of the reaction tank due to over violent reaction in the reaction tank; the released poisonous and harmful gas and splashed liquid can cause personal injury to operators who put in materials; that is to say, the retort of the prior art lacks a safe and reliable material feeding unit, and then can reduce and cause the threat to operating personnel's personal safety.

Disclosure of Invention

The invention aims to solve the technical problem of overcoming the defects of the prior art and provides a chemical reaction tank feeding device which can automatically feed materials and is safer and more reliable in the feeding process.

The technical scheme of the invention is to provide a chemical reaction tank feeding device with the following structure: the reaction tank comprises a support arranged above a reaction tank, wherein a material barrel for containing materials is arranged on the support, a cross rod is connected to the support in a sliding manner below the material barrel, a swinging plate is rotatably connected to one end, facing the material barrel, of the cross rod, and the swinging plate is connected with the cross rod through a butting device; a cavity used for containing materials falling from the charging barrel is arranged on one side of the swinging plate, which faces the charging barrel, a first vertical plate and a second vertical plate which are sequentially abutted against or separated from the upper end part of the swinging plate are arranged on the support, and the first vertical plate and the second vertical plate are respectively positioned on two sides of the upper end part of the swinging plate; a first baffle and a second baffle which are parallel to each other are respectively arranged on two sides of the cavity, and a rotating shaft between the cross rod and the swinging plate is positioned between the first baffle and the second baffle; the reaction tank is rotatably connected with a transmission plate, the transmission plate is provided with a first cylindrical pin which is used for abutting against or separating from a first baffle on the cavity, the transmission plate is provided with a second cylindrical pin which is used for abutting against or separating from a second baffle on the cavity, and the first cylindrical pin and the second cylindrical pin are arranged in parallel; and the reaction tank is provided with a cylinder for driving the transmission plate to rotate.

Preferably, the cross bar is connected to the support in a sliding manner below the charging barrel, that is, the guide sleeve is arranged on the support, the cross bar is connected to the guide sleeve in a sliding manner, and the cross bar is connected to the guide sleeve in a sliding manner along the horizontal direction.

Preferably, the pendulum plate is connected with the cross rod through the abutting device, that is, the cross rod is sleeved with the pressure spring, one end of the pressure spring abuts against the guide sleeve, and the other end of the pressure spring abuts against the pendulum plate.

As an improvement of the invention, two ends of the first baffle plate and the second baffle plate are respectively connected through a connecting plate, and the first baffle plate, the two connecting plates and the second baffle plate are connected to form a cavity.

As an improvement of the invention, a first open slot for abutting against or separating from the first cylindrical pin is arranged on the first baffle plate, and the cross section of the first open slot is in a V-shaped structure; the transmission plate is provided with a first through hole, and the first cylindrical pin is positioned in the first through hole.

As an improvement of the invention, a second open slot for abutting against or separating from a second cylindrical pin is arranged on the second baffle plate, and the cross section of the second open slot is in a V-shaped structure; and a second through hole is formed in the transmission plate, and the second cylindrical pin is positioned in the second through hole.

As an improvement of the present invention, the fact that the rotating shaft between the cross bar and the swing plate is located between the first baffle and the second baffle means that the swing plate is rotatably connected to the cross bar through a hinge point, and the hinge point is located between the first baffle and the second baffle along the length direction of the swing plate.

As an improvement of the invention, the cylinder body of the air cylinder is rotationally connected to the reaction tank, and the output end of the air cylinder is rotationally connected to the transmission plate.

As an improvement of the invention, the first vertical plate and the second vertical plate are arranged in parallel, and the first vertical plate and the second vertical plate are both positioned above the cross rod.

After the structure is adopted, compared with the prior art, the chemical reaction tank feeding device has the advantages that the transmission plate is driven to rotate by the air cylinder, and the second cylindrical pin and the first cylindrical pin on the transmission plate are sequentially matched with the second baffle and the first baffle on the swinging plate; when the second cylindrical pin on the transmission plate is matched with the second baffle on the swinging plate, the upper end part of the swinging plate is tightly propped against the second vertical plate, the opening of the cavity on the swinging plate faces the discharge port direction of the charging barrel, and materials discharged from the charging barrel can fall into the cavity; the swinging plate is pushed to the position right above a feed inlet of the reaction tank along with the rotation of the transmission plate, the first cylindrical pin starts to be matched with the first baffle, the upper end part of the swinging plate is tightly abutted against the first vertical plate, the swinging plate rotates relative to the cross rod, a cavity opening on the swinging plate faces the direction of the feed inlet of the reaction tank, and therefore materials contained in the cavity can fall into the reaction tank due to the self gravity; the swing plate is always abutted against the transmission plate under the action of the elastic force of the pressure spring, namely a first baffle and a second baffle on the swing plate are respectively matched with or separated from a first cylindrical pin and a second cylindrical pin on the transmission plate; whole process of puting in material need not that operating personnel stands and goes on near retort feed inlet, and then can avoid operating personnel to be splashed by the material when puting in the material, also can avoid operating personnel to inhale poisonous and harmful gas when puting in the material, and in a word, the personal safety that can put in material and operating personnel automatically through the device obtains the guarantee. In conclusion, the invention provides the chemical reaction tank feeding device which can automatically feed materials and is safer and more reliable in the feeding process.

Drawings

FIG. 1 is a schematic view of a chemical reaction tank feeding device of the present invention.

FIG. 2 is a view showing a state where the opening formed by the cavity and the driving plate faces the feed port of the reaction tank in the present invention.

FIG. 3 is a schematic view of the structure of the cavity of the wobble plate of the present invention.

Fig. 4 is a schematic structural view of the driving plate of the present invention.

Shown in the figure: 1. the device comprises a first baffle, a second baffle, a first cylindrical pin, a second cylindrical pin, a first vertical plate, a second vertical plate, a reaction tank, a support, a charging barrel, a cross rod, a swinging plate, a cavity, a transmission plate, a cylinder, a guide sleeve, a pressure spring, a connecting plate, a first opening groove, a second opening groove, a first through hole, a second through hole, a connecting plate, a driving plate.

Detailed Description

The invention is further described with reference to the following figures and detailed description.

As shown in the figure, the chemical reaction tank feeding device comprises a support 8 arranged above a reaction tank 7, a material barrel 9 for containing materials is arranged on the support 8, a cross rod 10 is connected to the support 8 below the material barrel 9 in a sliding manner, a swinging plate 11 is connected to one end, facing the material barrel 9, of the cross rod 10 in a rotating manner, and the swinging plate 11 is connected with the cross rod 10 through a butting device; a cavity 12 used for containing materials falling from the charging barrel 9 is formed in one side, facing the charging barrel 9, of the swinging plate 11, a first vertical plate 5 and a second vertical plate 6 which are used for being tightly abutted or separated from the upper end of the swinging plate 11 in sequence are arranged on the support 8, and the first vertical plate 5 and the second vertical plate 6 are respectively located on two sides of the upper end of the swinging plate 11; a first baffle plate 1 and a second baffle plate 2 which are parallel to each other are respectively arranged at two sides of the cavity 12, and a rotating shaft between the cross rod 10 and the swinging plate 11 is positioned between the first baffle plate 1 and the second baffle plate 2; a transmission plate 13 is rotatably connected to the reaction tank 7, a first cylindrical pin 3 used for abutting against or separating from a first baffle plate 1 on the cavity 12 is arranged on the transmission plate 13, a second cylindrical pin 4 used for abutting against or separating from a second baffle plate 2 on the cavity 12 is arranged on the transmission plate 13, and the first cylindrical pin 3 and the second cylindrical pin 4 are arranged in parallel; the reaction tank 7 is provided with a cylinder 14 for driving the transmission plate 13 to rotate.

The support 8 is connected with a cross rod 10 in a sliding manner below the charging barrel 9, that is, the guide sleeve 15 is arranged on the support 8, the cross rod 10 is connected to the guide sleeve 15 in a sliding manner, and the cross rod 10 is connected to the guide sleeve 15 in a sliding manner along the horizontal direction.

The connection between the swing plate 11 and the cross rod 10 through the abutting device means that the cross rod 10 is sleeved with a pressure spring 16, one end of the pressure spring 16 abuts against the guide sleeve 15, and the other end of the pressure spring abuts against the swing plate 11.

The two ends of the first baffle 1 and the second baffle 2 are respectively connected through a connecting plate 17, and the first baffle 1, the two connecting plates 17 and the second baffle 2 are connected to form a cavity 12, as shown in fig. 3.

The first baffle 1 is provided with a first open slot 18 which is used for being tightly pressed against or separated from the first cylindrical pin 3, and the section of the first open slot 18 is in a V-shaped structure; the driving plate 13 is provided with a first through hole 19, and the first cylindrical pin 3 is located in the first through hole 19. When the first baffle plate 1 is matched with the first cylindrical pin 3, the end part of the first baffle plate 1 can rotate in the area of the first through hole 19, namely, the first through hole 19 provides a rotating space for the rotation of the end part of the first baffle plate 1.

A second open slot 20 used for being tightly abutted against or separated from the second cylindrical pin 4 is arranged on the second baffle 2, and the section of the second open slot 20 is in a V-shaped structure; the driving plate 13 is provided with a second through hole 21, and the second cylindrical pin 4 is positioned in the second through hole 21. When the second baffle plate 2 is matched with the second cylindrical pin 4, the end part of the second baffle plate 2 can rotate in the area of the second through hole 21, namely, the second through hole 21 provides a rotating space for the rotation of the end part of the second baffle plate 2.

The fact that the rotating shaft between the cross rod 10 and the swinging plate 11 is located between the first baffle plate 1 and the second baffle plate 2 means that the swinging plate 11 is rotatably connected to the cross rod 10 through a hinge point 22, and the hinge point 22 is located between the first baffle plate 1 and the second baffle plate 2 along the length direction of the swinging plate 11; in this way, the opening formed by the cavity 12 on the swing plate 11 and the surface of the transmission plate 13 can deflect relative to the cross bar 10, and when the upper end of the swing plate 11 is matched with the second vertical plate 6, the opening faces upwards, namely the opening formed by the cavity 12 on the swing plate 11 and the surface of the transmission plate 13 faces the discharge port of the charging barrel 9, and the material discharged from the discharge port of the charging barrel 9 can fall into the cavity 12, as shown in fig. 1; when the upper end part of the swinging plate 11 is matched with the first vertical plate 5, the swinging plate 11 rotates clockwise relative to the right end part of the cross rod 10, the opening faces downwards, namely the opening formed by the cavity 12 on the swinging plate 11 and the surface of the transmission plate 13 faces the direction of a feed inlet of the reaction tank 7, and the material in the cavity 12 falls into the reaction tank 7 under the action of self gravity; generally speaking, the adjustment of the opening orientation of the cavity 12 is realized by adjusting the rotation angle of the swing plate 11 relative to the hinge point 22, the first vertical plate 5 and the second vertical plate 6 play a role in limiting, and the first vertical plate 5 and the second vertical plate 6 can also play a role in a fulcrum when being respectively contacted with the upper end of the swing plate 11, and the swing plate 11 can rotate around the fulcrum, so as to adjust the opening orientation of the cavity 12.

The cylinder body of the air cylinder 14 is rotationally connected to the reaction tank 7, and the output end of the air cylinder 14 is rotationally connected to the transmission plate 13.

The first and second risers 5 and 6 are arranged in parallel, and both the first and second risers 5 and 6 are located above the cross bar 10, as shown in fig. 1 and 2.

The working principle is as follows: firstly, the swinging plate 11 is located at the position shown in fig. 1, the upper end part of the swinging plate 11 is abutted against the second vertical plate 6 on the support 8, the second open slot 20 on the second baffle plate 2 is matched with the second cylindrical pin 4 on the transmission plate 13, the opening formed by the cavity 12 of the lower end part of the swinging plate 11 and the surface of the transmission plate 13 is upward, namely the opening faces to the direction of the discharge port at the lower end of the charging barrel 9, and the material discharged from the discharge port of the charging barrel 9 can fall into the cavity 12;

then, the air cylinder 14 works to push the transmission plate 13 to rotate anticlockwise on the bracket 8, the second cylindrical pin 4 on the transmission plate 13 is matched with the second open slot 20 to push the swinging plate 11 to rotate around the hinge point 22 and push the swinging plate 11 to move leftwards together with the cross rod 10, and the pressure spring 16 is compressed to contract and deform; in the process that the swinging plate 11 moves leftwards, the cavity 12 at the lower end of the swinging plate 11 also moves towards the feed inlet of the reaction tank 7; until the second cylindrical pin 4 is separated from the second open slot 20, the first cylindrical pin 3 is tightly abutted against the first open slot 18, and the upper end part of the swing plate 11 is tightly abutted against the first vertical plate 5, as shown in fig. 2, at this time, the opening of the cavity 12 faces downwards, namely, the opening formed by the cavity 12 at the lower end part of the swing plate 11 and the surface of the transmission plate 13 faces towards the feed inlet direction of the reaction tank 7, and the material located in the cavity 12 slides into the reaction tank 7 under the action of self gravity, so that the action of automatically feeding the material into the reaction tank 7 is realized.

The above description is only for the preferred embodiment of the present invention, and is not intended to limit the scope of the present invention. Any modification, equivalent replacement, and improvement made within the scope of the claims of the present invention should be included in the protection scope of the present invention.

Claims (7)

1. The utility model provides a chemical reaction jar material feeding unit, it is including setting up support (8) above retort (7), its characterized in that: a charging barrel (9) used for containing materials is arranged on the support (8), a cross rod (10) is connected to the support (8) below the charging barrel (9) in a sliding mode, a swinging plate (11) is connected to one end, facing the charging barrel (9), of the cross rod (10) in a rotating mode, and the swinging plate (11) is connected with the cross rod (10) through a butting device; a cavity (12) used for containing materials falling from the charging barrel (9) is formed in the side, facing the charging barrel (9), of the swinging plate (11), a first vertical plate (5) and a second vertical plate (6) which are used for being sequentially abutted against or separated from the upper end of the swinging plate (11) are arranged on the support (8), and the first vertical plate (5) and the second vertical plate (6) are respectively located on two sides of the upper end of the swinging plate (11); a first baffle (1) and a second baffle (2) which are parallel to each other are respectively arranged at two sides of the cavity (12), and a rotating shaft between the cross rod (10) and the swinging plate (11) is positioned between the first baffle (1) and the second baffle (2); a transmission plate (13) is rotatably connected to the reaction tank (7), a first cylindrical pin (3) which is tightly abutted or separated from a first baffle (1) on the cavity (12) is arranged on the transmission plate (13), a second cylindrical pin (4) which is tightly abutted or separated from a second baffle (2) on the cavity (12) is arranged on the transmission plate (13), and the first cylindrical pin (3) and the second cylindrical pin (4) are arranged in parallel; the reaction tank (7) is provided with a cylinder (14) for driving the transmission plate (13) to rotate; the support (8) is connected with a cross rod (10) below the charging barrel (9) in a sliding manner, namely, a guide sleeve (15) is arranged on the support (8), the cross rod (10) is connected to the guide sleeve (15) in a sliding manner, and the cross rod (10) is connected to the guide sleeve (15) in a sliding manner along the horizontal direction; the connection of the swing plate (11) and the cross rod (10) through the abutting device means that a pressure spring (16) is sleeved on the cross rod (10), one end of the pressure spring (16) abuts against the guide sleeve (15), and the other end of the pressure spring abuts against the swing plate (11).

2. The chemical reaction tank feeding device according to claim 1, characterized in that: the two ends of the first baffle (1) and the two ends of the second baffle (2) are respectively connected through a connecting plate (17), and the first baffle (1), the two connecting plates (17) and the second baffle (2) are connected to form a cavity (12).

3. The chemical reaction tank feeding device according to claim 1, characterized in that: a first open slot (18) used for being tightly pressed against or separated from the first cylindrical pin (3) is formed in the first baffle plate (1), and the section of the first open slot (18) is of a V-shaped structure; a first through hole (19) is formed in the transmission plate (13), and the first cylindrical pin (3) is located in the first through hole (19).

4. The chemical reaction tank feeding device according to claim 1, characterized in that: a second open slot (20) which is used for being tightly pressed against or separated from the second cylindrical pin (4) is arranged on the second baffle (2), and the section of the second open slot (20) is in a V-shaped structure; the transmission plate (13) is provided with a second through hole (21), and the second cylindrical pin (4) is positioned in the second through hole (21).

5. The chemical reaction tank feeding device according to claim 1, characterized in that: the fact that the rotating shaft between the cross rod (10) and the swinging plate (11) is located between the first baffle plate (1) and the second baffle plate (2) means that the swinging plate (11) is rotatably connected to the cross rod (10) through a hinge point (22), and the hinge point (22) is located between the first baffle plate (1) and the second baffle plate (2) along the length direction of the swinging plate (11).

6. The chemical reaction tank feeding device according to claim 1, characterized in that: the cylinder body of the air cylinder (14) is rotationally connected to the reaction tank (7), and the output end of the air cylinder (14) is rotationally connected to the transmission plate (13).

7. The chemical reaction tank feeding device according to claim 1, characterized in that: the first vertical plate (5) and the second vertical plate (6) are arranged in parallel, and the first vertical plate (5) and the second vertical plate (6) are located above the cross rod (10).

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