CN117282113A - Albumin peptide production device and process - Google Patents

Abstract

The invention relates to the technical field of albumin peptide production, in particular to an albumin peptide production device and process, wherein the albumin peptide production device comprises a cylinder, an atomizer, a first air inlet and a second air inlet; the cylinder body is internally provided with a cavity, the first air inlet is formed in the top of the cavity, the maximum atomization range of the atomizer is located right below the first air inlet, the second heating mechanism is located in the cavity, the second air inlet is located right below the atomizer, the second air inlet is smaller than the first air inlet, and the wind speed of the second air inlet is larger than that of the first air inlet. Through the cooperation of atomizer and first air intake, atomizer spun atomized liquid is in hot-blast completely, through the cooperation setting of first air intake and second air intake, can form the vortex in the cavity, and big liquid drop after the atomizing is influenced by self gravity and enters into in the vortex, improves its dwell time in the cavity, and the little liquid drop after the atomizing receives hot-blast blowing, can be closer to the inner wall of cavity, avoids excessive drying.

Description

Albumin peptide production device and process

Technical Field

The invention relates to the technical field of albumin peptide production, in particular to an albumin peptide production device and process.

Background

The production of albumin peptide needs to be through spray drying process, and current spray drying tower atomising head can lead to the inhomogeneous owing to nozzle jam or wall built-up phenomenon atomizing liquid droplet size when atomizing the liquid droplet for the drying of partly liquid albumin peptide is incomplete, and when current counter-current spray drying tower is to atomizing albumin peptide, the liquid droplet also can flow along with hot-blast, can effectively increase hot-blast and atomizing liquid droplet's area of contact, but also can increase atomizing droplet and stay in the drying tower time, makes the time in the high temperature environment of drying albumin peptide overlength, takes place the metamorphism easily.

Disclosure of Invention

Accordingly, it is necessary to provide an apparatus and a process for producing albumin peptide, which are capable of solving the problem that the deterioration probability of albumin peptide cannot be reduced at the time of improving the drying efficiency of albumin peptide.

The above purpose is achieved by the following technical scheme:

the albumin peptide production device comprises a cylinder body, a feeding mechanism, a first heating mechanism, a second heating mechanism, a detection mechanism and a receiving mechanism; a cavity is arranged in the cylinder body, and the feeding mechanism comprises an atomizer which is used for atomizing the liquid solution entering the cavity; the first heating mechanism comprises a first air inlet and a first heating component, the first air inlet is formed in the top of the cavity, the atomizer is arranged at the middle position of the first air inlet, the atomization range of the atomizer is located right below the first air inlet, and the first heating component is used for providing stable hot air for the first air inlet.

The second heating mechanism is located the cavity, and the second heating mechanism includes second air intake and second heating element, and the second air intake is located the atomizer under, and the second air intake is less than first air intake, and the second heating element is used for providing stable hot-blast to the second air intake.

The detection mechanism can detect the size of the liquid drops after atomization of the atomizer, and control the wind speed of the second air inlet, when the number of the large liquid drops after atomization is detected to be larger than a preset value, the wind speed of the second air inlet is increased, and the wind speed of the second air inlet is larger than the wind speed of the first air inlet.

The receiving mechanism is used for receiving the albumin peptide after drying in the cavity.

Preferably, the first heating assembly comprises a first air conveying pipe, a first air heater and a pressure valve; the cylinder is internally provided with a ring groove, the ring groove is arranged around the first air inlet, the first air conveying pipe is arranged outside the cylinder and communicated with the ring groove, the first air heater is arranged at one end of the first air conveying pipe far away from the cylinder, the pressure valves are arranged in a plurality, the pressure valves are uniformly arranged between the ring groove and the first air inlet, one end of each pressure valve is positioned in the ring groove, and the other end of each pressure valve is positioned in the first air inlet.

Preferably, the second heating element includes fixed plate, air-supply line, second air-supply line and second air heater, and the fixed plate is installed in the cavity, and the air-supply line is installed on the fixed plate, and the second air intake is seted up on the air-supply line, and the one end of second air-supply line is installed on the air-supply line, and second air-supply line and second air intake intercommunication, and the one end that the second air intake was kept away from to the second air-supply line runs through the barrel, and the one end that the second air intake was kept away from to the second air heater is installed in the second air-supply line.

Preferably, the detection mechanism comprises a plurality of laser sensors, the laser sensors are arranged at the top of the cavity and distributed in a circumferential array by taking the atomizer as a center point, the laser sensors are used for downward detection, and the sensors are electrically connected with the second hot air machine.

Preferably, the feeding mechanism further comprises a hopper and a feeding part, the hopper is arranged at the top of the cylinder, the bottom of the hopper penetrates through the cylinder, the bottom of the hopper is located in the middle of the first air inlet, the atomizer is arranged at the bottom of the hopper, and the feeding part is used for supplementing albumin peptide into the hopper.

Preferably, the cylinder body is provided with an observation window, and the observation window is communicated with the cavity.

Preferably, the receiving mechanism comprises a conical barrel, a receiving barrel and a power assembly, wherein the conical barrel is arranged in the barrel body, the conical barrel is communicated with the cavity, the conical barrel is positioned below the second air inlet, and the power assembly is used for extracting albumin peptide in the conical barrel into the receiving barrel.

Preferably, the power component comprises a material suction pipe and an exhaust fan, one end of the material suction pipe is connected with the bottom of the conical barrel, and the other end of the material suction pipe is connected with the material collecting barrel.

Preferably, the surface of the cylinder body is provided with a through hole, the pumping pipe penetrates through the through hole to be connected with the conical cylinder, and the exhaust fan is arranged in the pumping pipe and is used for pumping albumin peptide in the conical cylinder.

The invention also provides a production process of the albumin peptide, which comprises the following steps:

s1, starting the first heating mechanism and the second heating mechanism to enable the first air inlet and the second air inlet to blow hot air into the cavity.

S2, conveying albumin peptide to be dried into the cavity through the feeding mechanism, atomizing the albumin peptide through the atomizer, and drying the albumin peptide through hot air provided by the first air inlet and the second air inlet.

S3, detecting the atomization degree of the atomizer on the albumin peptide by the detection mechanism, adjusting the wind speed of the second air inlet, if the number of the atomized large liquid drops is larger than a preset value, increasing the wind speed of the second air inlet, increasing the difference value between the wind speed of the first air inlet and the wind speed of the second air inlet, and increasing the vortex range so that the large liquid drops can be fully dried.

S4, collecting the dried albumin peptide by a receiving mechanism.

The beneficial effects of the invention are as follows: set up the atomizer, can atomize liquid albumin peptide, increase its surface area, can promote the evaporation of moisture, through the cooperation of atomizer and first air intake, atomizer spun atomized liquid is in hot-blast completely, can fully contact with hot-blast, cooperation through first air intake and second air intake sets up, can form the vortex in the cavity, the vortex is in between first air intake exhaust hot-blast and the second air intake exhaust hot-blast, big liquid drop after the atomizing is influenced by self gravity and enters into the vortex, improve its dwell time in the cavity, increase its degree of dryness, and the liquid drop after the atomizing receives hot-blast influence, can be closer to the inner wall of cavity, keep away from the vortex, and collect by receiving material mechanism, avoid excessive drying.

Drawings

Fig. 1: the structure schematic diagram of the albumin peptide production device is provided for the embodiment of the invention;

fig. 2: a top view of an albumin peptide production device provided by the embodiment of the invention;

FIG. 3 is a cross-sectional view taken along the direction A-A in FIG. 2;

FIG. 4 is a cross-sectional view taken along the direction B-B in FIG. 2;

FIG. 5 is a flow simulation diagram showing that the number of large droplets is larger than a preset value after the atomization of albumin peptide in the albumin peptide production device provided by the embodiment of the invention;

FIG. 6 is a flow simulation diagram showing that the number of large droplets of atomized albumin peptide is smaller than a preset value in an albumin peptide production device according to an embodiment of the present invention.

Wherein: 100. a cylinder; 101. a cavity; 102. an atomizer; 103. a first air inlet; 104. a second air inlet; 105. a first air delivery pipe; 106. a first air heater; 107. a pressure valve; 108. a ring groove; 109. a fixing plate; 110. an air inlet pipe; 111. a second air delivery pipe; 112. a second air heater; 113. a laser sensor; 114. a hopper; 115. an observation window; 116. a storage barrel; 117. a material conveying pipe; 118. a conical cylinder; 119. a material collecting barrel; 120. a material pumping pipe; 121. and (5) an exhaust fan.

Detailed Description

The present invention will be further described in detail below with reference to examples, which are provided to illustrate the objects, technical solutions and advantages of the present invention. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention.

The numbering of components herein, such as "first," "second," etc., is used merely to distinguish between the described objects and does not have any sequential or technical meaning. The terms "coupled" and "connected," as used herein, are intended to encompass both direct and indirect coupling (coupling), unless otherwise indicated. In the description of the present invention, it should be understood that the terms "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element in question must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention.

In the present invention, unless expressly stated or limited otherwise, a first feature "up" or "down" a second feature may be the first and second features in direct contact, or the first and second features in indirect contact via an intervening medium. Moreover, a first feature being "above," "over" and "on" a second feature may be a first feature being directly above or obliquely above the second feature, or simply indicating that the first feature is level higher than the second feature. The first feature being "under", "below" and "beneath" the second feature may be the first feature being directly under or obliquely below the second feature, or simply indicating that the first feature is less level than the second feature.

As shown in fig. 1 to 6, the embodiment of the invention provides an albumin peptide production device, which is suitable for drying albumin peptide and is also suitable for materials with properties influenced by excessive drying of other materials. The invention provides a production device of albumin peptide, which comprises a barrel 100, a feeding mechanism, a first heating mechanism, a second heating mechanism, a detection mechanism and a receiving mechanism; a cavity 101 is arranged in the cylinder 100, the feeding mechanism comprises an atomizer 102, and the atomizer 102 is used for atomizing the liquid solution entering the cavity 101; the first heating mechanism comprises a first air inlet 103 and a first heating component, the first air inlet 103 is formed in the top of the cavity 101, the atomizer 102 is arranged at the middle position of the first air inlet 103, the maximum atomization range of the atomizer 102 is located right below the first air inlet 103, and the first heating component is used for providing stable hot air for the first air inlet 103.

The second heating mechanism is located in the cavity 101, and the second heating mechanism includes second air intake 104 and second heating element, and second air intake 104 is located under atomizer 102, and the bore of second air intake 104 is less than the bore of first air intake 103, and second heating element is used for providing stable hot air to second air intake 104.

The detection mechanism can detect the size of the atomized liquid drops of the atomizer 102 and control the wind speed of the second air inlet 104, when detecting that the number of the atomized liquid drops is greater than a preset value, the wind speed of the second air inlet 104 is increased, and the wind speed of the second air inlet 104 is greater than the wind speed of the first air inlet 103.

The receiving mechanism is used for receiving the albumin peptide after drying in the cavity 101.

The setting atomizer 102 can atomize liquid albumin peptide, increase its surface area, can promote the evaporation of moisture, through the cooperation of atomizer 102 and first air intake 103, atomizer 102 spun atomized liquid is in hot-blast completely, can fully contact with hot-blast, through the cooperation setting of first air intake 103 and second air intake 104, can form the vortex in cavity 101, the vortex is in between first air intake 103 exhaust hot-blast and the second air intake 104 exhaust hot-blast, the big liquid drop after atomizing is influenced by self gravity and enters into the vortex, improve its dwell time in cavity 101, increase its degree of dryness, and the little liquid drop after atomizing receives hot-blast influence, can be closer to the inner wall of cavity 101, keep away from the vortex, and be received by receiving material mechanism, avoid excessive drying.

In the present embodiment, the first heating assembly includes a first air delivery pipe 105, a first air heater 106, and a pressure valve 107; the cylinder 100 is internally provided with the annular groove 108, the annular groove 108 is formed around the first air inlet 103, the first air conveying pipe 105 is arranged outside the cylinder 100, the first air conveying pipe 105 is communicated with the annular groove 108, the first air heater 106 is arranged at one end of the first air conveying pipe 105 far away from the cylinder 100, the first air heater 106 can supply hot air and convey the hot air to the annular groove 108 through the first air conveying pipe 105, the pressure valves 107 are provided with a plurality of pressure valves 107, the pressure valves 107 are uniformly arranged between the annular groove 108 and the first air inlet 103, one end of each pressure valve 107 is positioned in the annular groove 108, the other end of each pressure valve 107 is positioned in the first air inlet 103, the pressure valves 107 are positioned at positions above the first air inlet 103, so that hot air discharged from the pressure valves 107 can be sprayed to the bottom of a cavity through the direction of the first air inlet 103, the pressure valves 107 are distributed around the annular groove 108 in an array, and the uniformly distributed pressure valves 107 enable the hot air entering the first air inlet 103 to be uniformly filled at each position of the first air inlet 103, and meanwhile, the pressure valves 107 can regulate the hot air speed, so that the hot air from the first air inlet 103 is uniform and stable.

In this embodiment, the second heating assembly includes a fixing plate 109, an air inlet pipe 110, a second air delivery pipe 111 and a second air heater 112, the fixing plate 109 is installed in the cavity 101, the air inlet pipe 110 is installed on the fixing plate 109, the second air inlet 104 is opened on the air inlet pipe 110, one end of the second air delivery pipe 111 is installed on the air inlet pipe 110, the second air delivery pipe 111 is communicated with the second air inlet 104, one end of the second air delivery pipe 111 far away from the second air inlet 104 penetrates through the cylinder 100, the second air heater 112 is installed at one end of the second air delivery pipe 111 far away from the second air inlet 104, the second air heater 112 can generate hot air, the air speed of the hot air generated by the second air heater 112 is greater than the air speed of the hot air generated by the first air heater 106, the hot air sprayed out of the second air inlet 104 can be flushed into the hot air sprayed out of the first air inlet 103, and the two hot air flows relatively, the hot air sprayed from the first air inlet 103 is blown away by the hot air sprayed from the second air inlet 104 and flows towards the inner wall of the cavity 101, the temperature of the edge part of the hot air sprayed from the first air inlet 103 is slightly reduced after the edge part of the hot air sprayed from the first air inlet 103 contacts with the inner wall of the cavity 101, the speed of the hot air sprayed from the second air inlet 104 is gradually reduced to be consistent with that of the hot air sprayed from the first air inlet 103, then the hot air sprayed from the first air inlet 103 flows along with the hot air sprayed from the first air inlet 103, a gas vortex can be generated between the edge of the hot air sprayed from the first air inlet 103 and the edge of the hot air sprayed from the second air inlet 104, large liquid drops generated by the atomizer 102 are smaller than small liquid drops with smaller mass under the influence of wind force under the condition of larger self mass, the small liquid drops move towards the side wall of the cavity 101 along with the scattered air flows, the small liquid drops are collected by a collecting mechanism, the large liquid drops generated by the atomizer 102 can enter vortex flow, rotate along with the vortex, and increase the time remained in the cylinder 100, the large liquid drops generated by the atomizer 102 can be sufficiently dried, and meanwhile, the small liquid drops generated by the atomizer 102 are blown down to the vicinity of the inner wall of the cavity 101, so that the situation that the large liquid drops are excessively in a high-temperature environment can be avoided, and the quality of albumin peptide is prevented from being reduced.

In this embodiment, the detection mechanism includes a plurality of laser sensors 113, the laser sensors 113 are disposed at the top of the cavity 101, the plurality of laser sensors 113 are distributed in a circumferential array with the atomizer 102 as a center point, the laser sensors 113 are directed downward for detection, and the laser sensors 113 are electrically connected with the second air heater 112, the laser sensors 113 are located right above the vortex, when the number of large droplets generated by the atomizer 102 is greater than a preset value, the large droplets are densely distributed in the vortex and are easily gathered into a whole again, the laser sensors 113 can detect the number change of the large droplets, the second air heater 112 is controlled to increase the wind speed, so that the wind speed difference between the second air inlet 104 and the first air inlet 103 is increased, the range of the vortex is enlarged, the distance between the large droplets in the vortex is increased, the contact area between the large droplets and the hot air is ensured, so that the water in the large droplets is better evaporated, and the drying is completed; when the large liquid drops in the vortex flow are fewer, the laser sensor 113 controls the second air heater 112 to reduce the air speed, the vortex range formed by the hot air sprayed from the second air inlet 104 and the hot air sprayed from the first air inlet 103 is reduced, and the energy consumption can be reduced while the drying of the large liquid drops is better completed.

In this embodiment, feed mechanism still includes hopper 114 and interpolation portion, hopper 114 installs in the top of barrel 100, and the bottom of hopper 114 runs through barrel 100, the bottom of hopper 114 is in the middle part of first air intake 103, and atomizer 102 installs in the bottom of hopper 114, can keep in albumin peptide in hopper 114, and hopper 114 is the back taper, albumin peptide in hopper 114 can be to the bottom constantly gather, finally get into atomizer 102, spray in cavity 101 after atomizer 102 atomizes, interpolation portion is used for supplementing albumin peptide in the hopper 114, interpolation portion includes storage vat 116 and conveying pipeline 117, storage vat 116 is located the barrel 100 outside, the one end of conveying pipeline 117 is located hopper 114, the other end of conveying pipeline 117 is equipped with the pump, and the pump is in the albumin peptide in storage vat 116, the pump can be with the albumin peptide in the storage vat 116 pump to hopper 114.

In this embodiment, the barrel 100 is provided with an observation window 115, the observation window 115 is communicated with the cavity 101, and transparent glass is arranged in the observation window 115, so that the movement state of albumin peptide in the cavity 101 can be observed conveniently.

In this embodiment, receiving mechanism includes toper section of thick bamboo 118, receive storage bucket 119 and power component, toper section of thick bamboo 118 sets up in barrel 100, toper section of thick bamboo 118 and cavity 101 intercommunication, and toper section of thick bamboo 118 is located the below of second air intake 104, the great one end of toper section of thick bamboo 118 opening is located the top, the less one end of toper section of thick bamboo 118 is located the below, can fall into toper section of thick bamboo 118 after the albumin peptide in cavity 101 dries, the residue of albumin peptide in barrel 100 has been avoided in the setting of toper section of thick bamboo 118, the rate of recovery of albumin peptide has been improved, receive storage bucket 119 and toper section of thick bamboo 118 intercommunication, power component is arranged in extracting albumin peptide in the toper section of thick bamboo 118 to receive in the storage bucket 119.

In this embodiment, the power assembly includes a suction pipe 120 and a suction fan 121, one end of the suction pipe 120 is connected to the bottom of the cone 118, the other end of the suction pipe 120 is connected to the receiving barrel 119, and the suction fan 121 is disposed in the suction pipe 120 and is used for extracting albumin peptide in the cone 118.

In this embodiment, the surface of the cylinder 100 is provided with a through hole, and the pumping tube 120 passes through the through hole to be connected with the conical cylinder 118, so that the through hole facilitates the installation of the pumping tube 120 and the maintenance of the inside of the cylinder 100.

The invention also provides a production process of the albumin peptide, which comprises the following steps:

s1, starting a first heating fan and a second heating fan in a first heating mechanism and a second heating mechanism, enabling hot air generated by a first air heater 106 to enter a ring groove 108 through a first air conveying pipe 105, filling the ring groove 108, then jetting hot air in the ring groove 108 into a first air inlet 103 through a pressure valve 107, and blowing off the hot air to a second air inlet 104 through the guiding of the first air inlet 103; the hot air generated by the second air heater 112 enters the air inlet pipe 110 through the second air conveying pipe 111, and then is blown away from the second air inlet 104 to the first air inlet 103, so that the first air inlet 103 and the second air inlet 104 blow hot air into the cavity 101.

S2, conveying albumin peptide to be dried into the cavity 101 through a pump, conveying the albumin peptide in the storage vat 116 into the hopper 114 through a conveying pipe 117, enabling the albumin peptide in the hopper 114 to flow to the atomizer 102, spraying the albumin peptide into the cavity 101 through atomization of the atomizer 102, enabling the range of the albumin peptide sprayed into the cavity 101 by the atomizer 102 to be not more than the range of hot wind flowing into a second air inlet in a first air inlet, enabling the albumin peptide to flow downwards under the blowing of hot wind in the first air inlet, enabling the albumin peptide above the hot wind blowing area of the second air inlet 104 to flow upwards under the blowing of hot wind blown out in the second air inlet 104, enabling the upward hot wind and the downward hot wind to generate vortex after being opposite, enabling partial albumin peptide liquid drops with larger mass to rotate in the vortex, increasing the time of staying in the cavity 101, and drying the albumin peptide through the hot wind provided by the first air inlet 103 and the second air inlet 104.

S3, a laser sensor 113 in the detection mechanism can detect the atomization degree of the atomizer 102 on the albumin peptide, the wind speed of the second air inlet 104 can be adjusted through the detected quantity of atomized albumin peptide liquid drops, if the quantity of atomized large liquid drops is larger than a preset value, the data detected by the laser sensor 113 can promote the rotating speed of the second air heater 112 and improve the wind speed of the second air inlet 104, so that the difference value between the wind speed of the first air inlet 103 and the wind speed of the second air inlet 104 is improved, the spraying distance of hot air generated by the second air inlet 104 is increased, the vortex range is enlarged, the distribution of more albumin peptide large liquid drops in vortex is relatively uniform, and the large liquid drops can be fully dried.

S4, the dried albumin peptide falls into the conical barrel 118, and then is extracted by an exhaust fan 121 in a receiving mechanism, the albumin peptide in the conical barrel 118 is extracted into an extraction pipe 120, and then is sent into a receiving barrel 119 for collection.

The technical features of the above embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.

The foregoing examples illustrate only a few embodiments of the invention and are described in detail herein without thereby limiting the scope of the invention. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of protection of the present invention is to be determined by the appended claims.

Claims (10)

1. An albumin peptide production device, comprising: the device comprises a barrel, a feeding mechanism, a first heating mechanism, a second heating mechanism, a detection mechanism and a receiving mechanism; a cavity is arranged in the cylinder body, and the feeding mechanism comprises an atomizer which is used for atomizing the liquid solution entering the cavity; the first heating mechanism comprises a first air inlet and a first heating component, the first air inlet is formed in the top of the cavity, the atomizer is arranged in the middle of the first air inlet, the atomization range of the atomizer is positioned right below the first air inlet, and the first heating component is used for providing stable hot air for the first air inlet;

the second heating mechanism is positioned in the cavity and comprises a second air inlet and a second heating component, the second air inlet is positioned right below the atomizer and is smaller than the first air inlet, and the second heating component is used for providing stable hot air for the second air inlet;

the detection mechanism can detect the size of the atomized liquid drops of the atomizer and control the wind speed of the second air inlet, when the number of the atomized liquid drops is detected to be larger than a preset value, the wind speed of the second air inlet is increased, and the wind speed of the second air inlet is larger than the wind speed of the first air inlet;

the receiving mechanism is used for receiving the albumin peptide after drying in the cavity.

2. The albumin peptide production apparatus of claim 1 wherein the first heating assembly comprises a first air delivery line, a first air heater, and a pressure valve; the cylinder is internally provided with a ring groove, the ring groove is arranged around the first air inlet, the first air conveying pipe is arranged outside the cylinder and communicated with the ring groove, the first air heater is arranged at one end of the first air conveying pipe far away from the cylinder, the pressure valves are arranged in a plurality, the pressure valves are uniformly arranged between the ring groove and the first air inlet, one end of each pressure valve is positioned in the ring groove, and the other end of each pressure valve is positioned in the first air inlet.

3. The albumin peptide production device as claimed in claim 1, wherein the second heating assembly comprises a fixing plate, an air inlet pipe, a second air conveying pipe and a second air heater, the fixing plate is installed in the cavity, the air inlet pipe is installed on the fixing plate, the second air inlet is formed in the air inlet pipe, one end of the second air conveying pipe is installed on the air inlet pipe, the second air conveying pipe is communicated with the second air inlet, one end of the second air conveying pipe, far away from the second air inlet, penetrates the cylinder, and the second air heater is installed at one end of the second air conveying pipe, far away from the second air inlet.

4. The albumin peptide production device as claimed in claim 3, wherein the detection means comprises a plurality of laser sensors, the plurality of laser sensors are mounted on the top of the cavity, the plurality of laser sensors are distributed in a circumferential array with the atomizer as a center point, the laser sensors are directed downward for detection, and the sensors are electrically connected with the second hot air machine.

5. The albumin peptide production device according to claim 1, wherein the feeding mechanism further comprises a hopper and a feeding portion, the hopper is mounted on the top of the barrel, the bottom of the hopper penetrates through the barrel, the bottom of the hopper is located in the middle of the first air inlet, the atomizer is mounted on the bottom of the hopper, and the feeding portion is used for supplementing albumin peptide into the hopper.

6. The albumin peptide production device as claimed in claim 1, wherein the cartridge body is provided with an observation window, and the observation window is communicated with the cavity.

7. The albumin peptide production device according to claim 1, wherein the material receiving mechanism comprises a conical barrel, a material receiving barrel and a power assembly, the conical barrel is arranged in the barrel body, the conical barrel is communicated with the cavity, the conical barrel is positioned below the second air inlet, and the power assembly is used for extracting albumin peptide in the conical barrel into the material receiving barrel.

8. The apparatus for producing albumin peptide according to claim 7, wherein the power assembly comprises a suction pipe and an exhaust fan, one end of the suction pipe is connected with the bottom of the cone, the other end of the suction pipe is connected with the receiving barrel, and the exhaust fan is arranged in the suction pipe for extracting albumin peptide in the cone.

9. The albumin peptide production device as claimed in claim 8, wherein the surface of the cylinder is provided with a through hole, and the pumping tube is connected with the conical cylinder through the through hole.

10. A process for producing an albumin peptide, characterized by using the albumin peptide production apparatus according to any one of claims 1 to 9, comprising the steps of:

s1, starting a first heating mechanism and a second heating mechanism to enable a first air inlet and a second air inlet to blow hot air into a cavity;

s2, conveying albumin peptide to be dried into a cavity through a feeding mechanism, atomizing the albumin peptide through an atomizer, and drying the albumin peptide through hot air provided by a first air inlet and a second air inlet;

s3, detecting the atomization degree of the atomizer on the albumin peptide by the detection mechanism, adjusting the wind speed of the second air inlet, if the number of the atomized large liquid drops is larger than a preset value, increasing the wind speed of the second air inlet, increasing the difference value between the wind speed of the first air inlet and the wind speed of the second air inlet, and increasing the vortex range so that the large liquid drops can be fully dried;

s4, collecting the dried albumin peptide by a receiving mechanism.