CN220460588U - Quantitative feeder - Google Patents

Abstract

The utility model relates to the technical field of feeders, in particular to a quantitative feeder, which comprises a shell and a hopper. The hopper is arranged in the shell, the device cover is arranged on the shell and used for covering the hopper, the discharge hole is arranged below the hopper, the spline shaft is arranged at the discharge hole and connected with the motor in a transmission manner, the material in the hopper is discharged through rotation of the spline shaft, the fan-shaped water spray nozzle is arranged at the discharge hole, the water spray range of the fan-shaped water spray nozzle covers the discharge range of the discharge hole, and therefore the material is scattered, and subsequent dissolution is facilitated. When the utility model is used, the quantitative addition of the materials is realized, the heating of the materials is realized, and the materials are scattered through the fan-shaped water spray nozzle in the adding process, so that the utility model is beneficial to the rapid dissolving process of the materials and is convenient for use in production.

Description

Quantitative feeder

Technical Field

The utility model relates to the technical field of feeders, in particular to a quantitative feeder.

Background

In the industrial production process, quantitative addition and dissolution of powder and particle materials are often involved, and a quantitative feeder is arranged on a dissolution tank in the process, so that the quantitative addition and dissolution process of the powder or the particle materials is realized through quantitative addition and then stirring and dissolution in the process.

The existing quantitative feeder can generally realize quantitative addition of materials in the using process, but is easy to bond and agglomerate in the adding process, such as polypropylene powder materials and the like, so that inconvenience is brought to subsequent stirring and dissolution, and the production efficiency is affected.

Therefore, the quantitative feeder capable of enabling materials to be added more uniformly while quantitatively adding, so that the dissolution rate is improved, and the quantitative feeder is a problem to be solved in the prior art.

Disclosure of Invention

The utility model aims to overcome the defects in the prior art and provide a quantitative feeder so as to achieve the purposes of more uniformly adding powder or granular materials and improving the dissolution rate.

In order to achieve the above purpose, the utility model adopts the following technical scheme: the utility model provides a ration feeder, includes the casing, puts in the casing and installs the hopper, installs the integral key shaft in the discharge gate department of hopper below, and the casing is the bottom opening that does not have the shelter from in the below of discharge gate, and the integral key shaft is connected with motor drive, and fixed mounting has the inlet tube in the casing, is provided with fan-shaped water spout at the end of inlet tube, and fan-shaped water spout's water spray range covers the discharge range of discharge gate.

Further, a supporting groove is formed in the edge above the hopper and is matched with the shell wall of the shell, and the hopper is supported on the shell wall by the supporting groove.

Further, a device cover is arranged above the shell and covers the hopper, and a handle is arranged on the device cover.

Further, the spline shaft is provided with a connecting part outside the discharge hole, the connecting part is connected with a spline housing, and the other side of the spline housing is connected with a rotating shaft of the motor.

Further, the bottom of casing be provided with the mounting panel, the inboard fixed connection of inlet tube and mounting panel, motor, fan-shaped water spray nozzle, discharge gate and the bottom opening of casing below all are located the inboard of mounting panel, the outside of mounting panel is the control box, the motor inserts in the control box.

Further, an electric water valve is arranged on the water inlet pipe and is connected into the control box.

Further, the outer periphery of the hopper is coated and adhered with a silica gel heating plate, and the silica gel heating plate is connected into the control box.

Further, heat dissipation holes are arranged on the shells at two sides of the control box.

The utility model has the beneficial effects that: when the quick dissolving device is used, the material can be quantitatively added, the material can be heated, and the material is scattered through the fan-shaped water spray nozzle in the adding process, so that the quick dissolving process of the material is benefited, and the quick dissolving device is convenient to use in production.

Drawings

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

FIG. 2 is a schematic view of the internal hopper construction of the present utility model;

FIG. 3 is a schematic view of the structure of a discharge port of the hopper of the utility model;

FIG. 4 is a schematic view of the spline shaft of the present utility model;

fig. 5 is a schematic view of the internal structure of the housing of the present utility model.

Name corresponding to each label in the figure:

1. a housing; 11. a power line interface; 12. a heat radiation hole; 13. a water pipe interface; 14. a mounting port; 15. a loose leaf; 16. a housing wall; 17. a mounting plate; 171. a power supply terminal; 172. a circuit breaker; 173. an intermediate relay A; 174. an intermediate relay B; 175. a time relay A; 176. a time relay B; 18. a control box; 19. a bottom opening; 2. a device cover; 21. a handle; 3. a control panel; 31. a temperature control panel; 32. a time control panel; 33. a speed regulation panel; 34. an automatic start button; 35. a purge button; 36. an emergency stop button; 37. a lock; 4. a hopper; 41. a bucket body; 42. a support groove; 43. a discharge port; 431. a spline shaft; 432. a connection part; 433. a spline housing; 44. a silica gel heating plate; 5. a water inlet pipe; 51. an electric water valve; 52. a fixing clamp; 53. fan-shaped water spray nozzles; 6. and a motor.

Detailed Description

The technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model, and it is apparent that the described embodiments are only some embodiments of the present utility model, but not all embodiments, and all other embodiments obtained by those skilled in the art based on the embodiments of the present utility model are within the scope of protection of the present utility model.

Embodiments of the utility model:

as shown in fig. 1 to 5, in the present embodiment, a housing 1 is provided, in which a device cover 2 is placed on the housing 1, and a handle 21 is provided on the device cover 2.

A hopper 4 is mounted in the housing 1, wherein a support groove 42 is provided at the periphery of the hopper 4, which support groove 42 is in engagement with the housing wall 16 of the housing 1, the housing wall 16 being located in the support groove 42 when the hopper 4 is placed.

The installation plate 17 is arranged in the shell 1, the bottom of the front side of the installation plate 17 is sealed to form the control box 18, the bottom of the rear of the installation plate 17 is not shielded to form the bottom opening 19, the front side of the installation plate 17 is provided with the power connection terminal 171, the power connection terminal 171 is connected with a power line, the shell 1 is provided with the power line interface 11 matched with the power line, the power connection terminal 171 is connected with the circuit breaker 172, and the circuit breaker 172 is sequentially connected with the intermediate relay A173, the intermediate relay B174, the time relay A175 and the time relay B176.

The control cabinet comprises a shell 1, a mounting opening 14, a control panel 3, a lock 37, a temperature control panel 31, a time control panel 32, a speed regulation panel 33, an automatic start button 34, a clear button 35 and an emergency stop button 36, wherein the mounting opening 14 is arranged on the shell 1, the mounting opening 14 is positioned on the outer side of the control cabinet 18, the control panel 3 is arranged between the control panel 3 and the mounting opening 14 through a hinge 15, the temperature control panel 31, the time control panel 32, the speed regulation panel 33, the automatic start button 34, the clear button 35 and the emergency stop button 36 are arranged on the control panel 3, and heat dissipation holes 12 are formed on the shell 1 on two sides of the control cabinet 18.

A water inlet pipe 5 is arranged on the other side of the mounting plate 17, a water pipe connector 13 is correspondingly arranged on the shell 1, the water inlet pipe 5 is fixedly connected with the mounting plate 17 through a fixing clamp 52, an electric water valve 51 is arranged on the water inlet pipe 5, a fan-shaped water spray nozzle 53 is arranged at the outlet of the water inlet pipe 5, and the range of the fan-shaped water spray nozzle 53 covers the range of the discharge hole 43.

A spline shaft 431 is installed in the discharge hole 43 of the hopper 4, one end of the spline shaft 431 is connected with a spline housing 433 through a connecting part 432, the other end of the spline housing 433 is connected with a rotating shaft of a motor 6, the motor 6 is fixedly installed in the shell 1, and a silica gel heating plate 44 is adhered to the hopper body 41 of the hopper 4.

The principle of the utility model is as follows:

when the utility model is used, the feeder is used for feeding and dissolving powder materials, such as polypropylene powder and the like, and the feeder is arranged on a dissolving tank in the process, so that the quantitative feeding and dissolving process of the powder materials is realized.

When the material is added, firstly, the material is added into the hopper 4, then, the device cover 2 is covered, at the moment, the power supply is switched on, the emergency stop button 36 is closed, the automatic start button 34 is pressed, the automatic blanking process can be realized, the motor 6 drives the spline shaft 431 to rotate in the blanking process, the spline shaft 431 is common in the prior art, the surface of the spline shaft 431 is provided with a bulge and a groove, the bulge is contacted with the side wall of the discharge hole 43, the groove can continuously bring the material out in the rotating process of the spline shaft 431, the carried material is scattered through water mist sprayed by the fan-shaped water spray nozzle 53, the scattered material can be added into the stirring tank, the quantitative adding and dissolving process of the material is realized, and the fan-shaped water spray nozzle 35 in the process is conventional, and the structure, principle and use mode of the process are not repeated.

For the automatic adding process of the materials, the temperature of heating is set through the temperature control panel 31, the silica gel heating plate 44 is stuck on the surface of the hopper 4 and is used for the heating process of the materials in the hopper 4, the automatic starting button 34 is pressed at this moment, a circuit is connected, the silica gel heating plate 44 starts to automatically heat the materials in the hopper 4 at constant temperature, the existing silica gel heating plate 44 can realize the automatic constant temperature heating process, due to the fact that the existing silica gel heating plate 44 is not repeated in principle, when the temperature reaches a set value, the temperature control panel 31 outputs a signal, the intermediate relay A173 acts, the electric water valve 51 is started, the fan-shaped water spray nozzle 53 starts spraying, after a certain time is delayed, the time relay A175 acts, the motor 6 starts, the motor 6 drives the spline shaft 431 to rotate, the blanking process is realized, after a certain time is delayed, the intermediate relay B174 acts, the motor 6 is closed, the blanking is stopped, the time is delayed for a certain time, the time is 10s, the time relay B176 acts, the electric water valve 51 is closed, the automatic blanking process can be realized, the automatic blanking process is realized, when the motor button 35 in the control panel 3 is pressed, the blanking process is stopped, the emergency operation of the relay is stopped, the emergency operation is realized, the emergency operation of the relay is not continuously performed, and the intermittent operation is realized, the emergency operation is not is stopped, and the emergency operation is realized, and the device is stopped, and the like.

It should be clear that the above-mentioned process related to automatic control is only one of the existing embodiments, and many existing ways of realizing automatic control, such as by a single-chip microcomputer, etc., are included in the protection scope of the present utility model without departing from the core technical scheme of the present utility model.

Claims (8)

1. A doser, characterized in that: including casing (1), put and install hopper (4) in casing (1), install integral key (431) in discharge gate (43) department of hopper (4) below, casing (1) are bottom opening (19) that do not shelter from in the below of discharge gate (43), integral key (431) are connected with motor (6) transmission, fixed mounting has inlet tube (5) in casing (1), is provided with fan-shaped water spray nozzle (53) in the end of inlet tube (5), and the water spray scope of fan-shaped water spray nozzle (53) covers the discharge scope of discharge gate (43).

2. A doser as claimed in claim 1, wherein: the upper edge of the hopper (4) is provided with a supporting groove (42), the supporting groove (42) is matched with the shell wall (16) of the shell (1), and the hopper (4) is supported and placed on the shell wall (16) by means of the supporting groove (42).

3. A doser as claimed in claim 2, wherein: the device is characterized in that a device cover (2) is arranged above the shell (1), the device cover (2) covers the hopper (4), and a handle (21) is arranged on the device cover (2).

4. A doser as claimed in claim 1, wherein: the spline shaft (431) is provided with a connecting part (432) outside the discharge hole (43), the connecting part (432) is connected with a spline housing (433), and the other side of the spline housing (433) is connected with a rotating shaft of a motor (6).

5. A doser as claimed in claim 1, wherein: the bottom of casing (1) be provided with mounting panel (17), the inboard fixed connection of inlet tube (5) and mounting panel (17), motor (6), fan-shaped water spray nozzle (53), discharge gate (43) and bottom opening (19) of casing (1) below all are located the inboard of mounting panel (17), the outside of mounting panel (17) is control box (18), in motor (6) access control box (18).

6. A doser as set forth in claim 5 wherein: an electric water valve (51) is arranged on the water inlet pipe (5), and the electric water valve (51) is connected into the control box (18).

7. A doser as set forth in claim 5 wherein: the outer periphery of the hopper (4) is coated and adhered with a silica gel heating plate (44), and the silica gel heating plate (44) is connected into the control box (18).

8. A doser as set forth in claim 5 wherein: and heat dissipation holes (12) are arranged on the shells (1) at two sides of the control box (18).