CN220974623U - Additive pouring device - Google Patents

Abstract

The utility model discloses an additive pouring device which comprises a main cylinder, wherein a top cover is arranged at the upper end of the main cylinder, a feed inlet is formed in the top cover, a guide cylinder is arranged on the top cover, a through hole is formed in the guide cylinder, the upper end of the through hole is communicated with the feed inlet, a discharge hole is formed in the bottom of the main cylinder, the main cylinder comprises a containing cavity, the containing cavity is communicated with the bottom of the through hole and the discharge hole, a sliding sleeve is arranged on the guide cylinder and sleeved into the guide cylinder, the sliding sleeve can move up and down along the axial direction of the guide cylinder and can rotate along the axial direction of the guide cylinder, the sliding sleeve comprises a chassis, the outer wall of the chassis is connected with a sliding block through a bearing, and the outer wall of the sliding block is attached to the inner wall of the main cylinder. In the utility model, when the tank is filled, the sliding sleeve spirally descends under the action of the elasticity of the spring, the chassis applies pressure to the liquid, and the liquid flow rate of the discharge port is accelerated.

Description

Additive pouring device

Technical Field

The utility model relates to the technical field of filling equipment, in particular to an additive filling device.

Background

As shown in fig. 1, the additive currently applied to the new material on the environment-friendly surface of the photovoltaic cell needs to be subjected to barrel separation filling after stirring and fusion, a tank is arranged below the filling barrel 100, and is conveyed and moved through a production line, and is filled when being conveyed to the position right below the filling barrel 100.

The filling tube 100 is fed through the feeding channel 200 positioned above and discharged from the discharging channel 300 positioned below, the feeding channel 200 and the discharging channel 300 are both opened and closed through valve control, the additive is water-shaped liquid, the discharging flow rate of the discharging channel 300 positioned at the bottom is increased, the side edge of the upper part of the filling tube 100 is also provided with the air vent 400, and the air pressure above the liquid level in the filling tube 100 is increased by venting the air vent 400, so that the discharging flow rate of the discharging channel 300 is increased, and the production rhythm is accelerated.

Because the vent 400 is externally connected with pressure stabilizing equipment, when the discharge channel 300 discharges, the air pressure above the liquid level in the filling barrel 100 is basically kept stable, and the discharge speed of the discharge channel 300 is kept relatively uniform, but when the filling barrel 100 is about to be filled with the tank below the discharge channel, the liquid at the barrel opening at the upper end of the tank is easy to splash due to the faster discharge flow speed, if the liquid level height after the filling of the tank is reduced, the utilization rate of the tank is reduced.

Disclosure of utility model

The utility model aims to overcome the defects of the prior art, and provides an additive pouring device which has high pouring efficiency and is not easy to generate splashing phenomenon.

In order to achieve the above purpose, the technical scheme of the utility model is as follows:

The utility model provides an additive pouring device, including a main section of thick bamboo, the top cap is installed to main section of thick bamboo upper end, the top cap is equipped with the feed inlet, the guide cylinder is installed to the top cap, the guide cylinder is equipped with the through-hole, through-hole upper end and feed inlet intercommunication, main section of thick bamboo bottom is equipped with the discharge gate, main section of thick bamboo includes holds the chamber, hold chamber and through-hole bottom and discharge gate intercommunication, the guide cylinder installs the sliding sleeve, the sliding sleeve embolias the guide cylinder, the sliding sleeve can follow guide cylinder axial reciprocates and can follow guide cylinder axial rotation, the sliding sleeve includes the chassis, the chassis outer wall is connected with the slider through the bearing, slider outer wall and main section of thick bamboo inner wall laminating.

The inner side of the chassis is provided with a bulge, the guide cylinder is provided with a groove, and the bulge is inserted into the groove and can move along the inner wall of the groove.

The groove is spiral, and the bulge can move along the inner wall of the groove in a spiral way.

The sliding sleeve further comprises a ring sleeve positioned at the upper end of the chassis, the inner wall of the ring sleeve is attached to the outer wall of the guide cylinder, and the top of the ring sleeve is positioned above the spiral top of the groove.

The inner wall of the top of the ring sleeve is sealed with the gap of the main cylinder.

The chassis comprises a blade positioned below, and the blade can axially rotate along the sliding sleeve.

When the northern hemisphere is used, the sliding sleeve descends, the blades rotate anticlockwise, and when the southern hemisphere is used, the sliding sleeve descends, and the blades rotate clockwise.

The ring sleeve is sleeved with a spring, the bottom of the spring is propped against the chassis, and the top of the spring is propped against the top cover.

The discharge hole is controlled to be opened and closed by a valve.

The outer wall of the sliding block is sealed with the inner wall of the main cylinder through a sealing ring.

The beneficial effects of the utility model are as follows:

when the tank is filled, the sliding sleeve spirally descends under the action of the elasticity of the spring, the chassis applies pressure to liquid, and the liquid flow rate of the discharge port is accelerated.

The setting of spring, when liquid fills the jar bucket through the discharge gate, the spring is stretched gradually, and when the jar bucket about to accomplish to fill, the spring is in the free extension state this moment, holds the intracavity liquid and gets into the jar bucket by its self action of gravity, consequently the speed that liquid got into the jar bucket slows down to reduce jar bucket mouth department liquid and splash the emergence of phenomenon.

When the sliding sleeve spirally descends, the blades rotate and stir the liquid in the containing cavity, the sliding sleeve spirally descends to enable the blades to rotate, the rotation direction is the same as the rotation direction of the earth, the blades stir the liquid in the containing cavity, the liquid in the containing cavity generates vortex, the liquid enters the discharge port more smoothly, the discharge speed is accelerated, and the pouring speed of the tank is accelerated.

Drawings

FIG. 1 is a schematic diagram of the background art;

FIG. 2 is a cross-sectional view of an embodiment;

FIG. 3 is an enlarged view of FIG. 2 at A;

FIG. 4 is a perspective view of a guide cylinder according to an embodiment;

Fig. 5 is a cross-sectional view of the chassis in an embodiment.

In the figure: the device comprises a main cylinder 1, a top cover 11, a feed inlet 111, a containing cavity 12, a discharge outlet 13, a guide cylinder 2, a through hole 21, a groove 22, a spring 3, a sliding sleeve 4, a chassis 41, a bulge 411, a blade 412, a ring 42, a valve 5, a tank 6, a sliding block 7, a sealing ring 8, a filling cylinder 100, a feed channel 200, a discharge channel 300 and a vent 400.

Detailed Description

The technical scheme of the utility model is further described below through examples and with reference to the accompanying drawings.

As shown in fig. 2-5, an additive pouring device comprises a main barrel 1, wherein the main barrel 1 is of a cylindrical barrel structure with an opening at the top, a containing cavity 12 is arranged in the main barrel 1, a discharging hole 13 is formed in the bottom of the main barrel 1, the discharging hole 13 is communicated with the lower end of the containing cavity 12, the opening and closing of the discharging hole 13 are controlled by a valve 5, a tank barrel 6 is placed in the main barrel 1, water-shaped liquid can be filled in the main barrel 1, and the liquid is poured into the tank barrel 6 through the discharging hole 13, the valve 5 and a connecting pipeline.

The top cover 11 is installed to main section of thick bamboo 1 upper end, and top cover 11 is equipped with feed inlet 111, and the feed inlet 111 switching is controlled through setting up the valve to top cover 11 upper end, and the incoming material can be followed feed inlet 111 and is got into appearance chamber 12.

As shown in fig. 2 and 4, the top cover 11 is provided with a guide cylinder 2, the guide cylinder 2 is positioned in the accommodating cavity 12, the guide cylinder 2 is of a cylindrical structure, the upper end of the guide cylinder 2 is fixedly connected with the top cover 11, and the bottom of the guide cylinder 2 is positioned above the inner wall of the bottom of the main cylinder 1. The guide cylinder 2 is provided with a through hole 21, the through hole 21 penetrates the guide cylinder 2 up and down, the upper end of the through hole 21 is communicated with the feeding hole 111, and the bottom of the through hole 21 is communicated with the containing cavity 12.

The guide cylinder 2 outer wall is equipped with recess 22, and recess 22 inwards is sunken along guide cylinder 2 outer wall, and recess 22 is upwards spiral from the bottom along guide cylinder 2 outer wall, sets up to left-hand (from top to bottom observing the direction, is right-hand in the use of southern ball) when northern hemisphere uses, and recess 22 spiral rise height is fifty percent to sixty percent of guide cylinder 2 overall height.

As shown in fig. 2, the guide cylinder 2 is provided with a sliding sleeve 4, the sliding sleeve 4 is sleeved into the guide cylinder 2, and the sliding sleeve 4 can move up and down along the axial direction of the guide cylinder 2 and can rotate along the axial direction of the guide cylinder 2. Specifically, the sliding sleeve 4 includes a chassis 41, the chassis 41 is in a disc structure, as shown in fig. 3 and 5, a protrusion 411 is provided on the inner side of the chassis 41, the protrusion 411 is inserted into the groove 22 and can move along the inner wall of the groove 22, and the protrusion 411 rises or falls along the spiral line direction of the groove 22.

The sliding sleeve 4 further comprises a ring sleeve 42 positioned at the upper end of the chassis 41, the ring sleeve 42 is of a cylindrical structure, the ring sleeve 42 extends upwards along the upper end face of the chassis 41, the inner wall of the ring sleeve 42 is attached to the outer wall of the guide cylinder 2, and when the sliding sleeve 4 can move up and down along the axial direction of the guide cylinder 2, the top of the ring sleeve 42 is always positioned above the spiral top of the groove 22, and the inner side of the top of the ring sleeve 42 is in clearance seal with the outer wall of the guide cylinder 2.

The chassis 41 includes a blade 412 located below, the blade 412 is plate-shaped, the blade 412 extends downward along the bottom surface of the chassis 41 and is uniformly distributed with 4 circumferentially, and when the sliding sleeve 4 rotates spirally, the blade 412 rotates axially along the sliding sleeve 4.

As shown in fig. 3, the outer wall of the chassis 41 is connected with a sliding block 7 through a bearing, the sliding block 7 is in a circular ring structure, the upper end face and the lower end face of the sliding block 7 are flush with the upper end face and the lower end face of the chassis 41, the outer wall of the sliding block 7 is attached to the inner wall of the main cylinder 1, the sliding sleeve 4 can drive the sliding block 7 to slide up and down when rotating in a spiral mode, and the outer wall of the sliding block 7 is sealed with the inner wall of the main cylinder 1 through a sealing ring 8.

The ring 42 is sleeved with the spring 3, the bottom of the spring 3 is propped against the chassis 41, and the top of the spring 3 is propped against the top cover 11.

Before the tank 6 is filled, the valve 5 below the discharge hole 13 is closed, the liquid is introduced into the feed hole 111, the liquid enters the containing cavity 12 through the through hole 21, the upper end of the liquid pushes the chassis 41 to rise spirally along with the rising of the liquid level in the containing cavity 12, the chassis 41 drives the sliding block 7 to rise together, and the spring 3 is compressed. The volume of liquid poured into the cavity 12 ensures that the tank 6 is poured once.

When the tank 6 is filled, the feed inlet 111 is closed, the valve 5 below the discharge outlet 13 is opened, the sliding sleeve 4 is spirally lowered under the action of the elasticity of the spring 3, the chassis 41 applies pressure to liquid, the liquid flow rate of the discharge outlet 13 is accelerated, when the sliding sleeve 4 spirally descends, the blades 412 rotate and stir the liquid in the accommodating cavity 12, when the northern hemisphere is used, the sliding sleeve 4 spirally descends to anticlockwise rotate (clockwise in the southern hemisphere), the direction of the northern hemisphere is the same as that of the earth rotation, and the liquid in the accommodating cavity 12 generates anticlockwise vortex, so that the liquid enters the discharge outlet 13 more smoothly, the discharge speed is accelerated, and the filling speed of the tank 6 is accelerated.

Due to the arrangement of the spring 3, when the liquid fills the tank 6 through the discharge hole 13, the spring 3 gradually stretches, when the tank 6 is about to finish filling, the spring 3 is in a free stretching state, and the liquid in the containing cavity 12 enters the tank 6 under the action of self gravity, so that the speed of the liquid entering the tank 6 is slowed down, and the liquid splashing phenomenon at the tank mouth of the tank 6 is reduced.

The foregoing description of the preferred embodiments of the utility model is not intended to limit the utility model to the precise form disclosed, and any such modifications, equivalents, and alternatives falling within the spirit and scope of the utility model are intended to be included within the scope of the utility model.

Claims (10)

1. An additive infusion device, characterized in that: including main section of thick bamboo (1), top cap (11) are installed to main section of thick bamboo (1) upper end, top cap (11) are equipped with feed inlet (111), guide cylinder (2) are installed to top cap (11), guide cylinder (2) are equipped with through-hole (21), through-hole (21) upper end with feed inlet (111) intercommunication, main section of thick bamboo (1) bottom is equipped with discharge gate (13), main section of thick bamboo (1) include appearance chamber (12), appearance chamber (12) with through-hole (21) bottom and discharge gate (13) intercommunication, sliding sleeve (4) are installed to guide cylinder (2), sliding sleeve (4) are emboliaed guide cylinder (2), sliding sleeve (4) can be followed guide cylinder (2) axial reciprocates just can be followed guide cylinder (2) axial rotation, sliding sleeve (4) include chassis (41), the chassis (41) outer wall is connected with slider (7) through the bearing, slider (7) outer wall with main section of thick bamboo (1) laminating.

2. An additive infusion device as claimed in claim 1, wherein: the inner side of the chassis (41) is provided with a bulge (411), the guide cylinder (2) is provided with a groove (22), and the bulge (411) is inserted into the groove (22) and can move along the inner wall of the groove (22).

3. An additive infusion device as claimed in claim 2, wherein: the groove (22) is spiral, and the protrusion (411) can move along the inner wall of the groove (22) in a spiral mode.

4. An additive infusion device according to claim 3, wherein: the sliding sleeve (4) further comprises a ring sleeve (42) positioned at the upper end of the chassis (41), the inner wall of the ring sleeve (42) is attached to the outer wall of the guide cylinder (2), and the top of the ring sleeve (42) is positioned above the spiral top of the groove (22).

5. An additive infusion device as set forth in claim 4, wherein: the inner wall of the top of the ring sleeve (42) is in clearance seal with the main cylinder (1).

6. An additive infusion device according to claim 3, wherein: the chassis (41) comprises a blade (412) positioned below, and the blade (412) can axially rotate along the sliding sleeve (4).

7. An additive infusion device as set forth in claim 6, wherein: when the northern hemisphere is used, the sliding sleeve (4) descends, the blade (412) rotates anticlockwise, and when the southern hemisphere is used, the sliding sleeve (4) descends, and the blade (412) rotates clockwise.

8. An additive infusion device as set forth in claim 4, wherein: the ring sleeve (42) is sleeved with a spring (3), the bottom of the spring (3) abuts against the chassis (41), and the top of the spring (3) abuts against the top cover (11).

9. An additive infusion device as claimed in claim 1, wherein: the discharge hole (13) is controlled to be opened and closed by a valve (5).

10. An additive infusion device as claimed in claim 1, wherein: the outer wall of the sliding block (7) is sealed with the inner wall of the main cylinder (1) through a sealing ring (8).