CN220634623U - High-efficient reducing mechanism of probiotics - Google Patents

Abstract

The utility model relates to the technical field of probiotic production, in particular to a high-efficiency probiotic smashing device which comprises a machine body, wherein a material blocking mechanism is arranged on the outer wall of the machine body and comprises a first motor and a dovetail groove, the outer wall of a rack is fixedly connected with a material blocking plate, the rack is slidably connected with the machine body through the dovetail groove processed on the surface of the machine body, the first motor drives a first bevel gear to rotate through the cooperation of the machine body and the material blocking mechanism, the first bevel gear drives a second bevel gear to rotate, a gear drives the rack to move, the rack drives the material blocking plate to move, a discharge hole is blocked, the situation that probiotic raw materials fall without being smashed for multiple times can be avoided, the working efficiency of the smashing device is improved, the probiotic raw materials can be prevented from being attached to the inner wall of the machine body through the cooperation of a shell and a stirring scraping mechanism, the use ratio of the probiotic raw materials is increased, and the working cost of the smashing device is reduced.

Description

An efficient crushing device for probiotics

Technical field

The utility model relates to the technical field of probiotic production, specifically an efficient crushing device for probiotics.

Background technique

With the improvement of living standards, people pay more and more attention to health and wellness. Probiotics are a type of active microorganisms that are beneficial to the host and play a very important role in human nutrition and health. By colonizing the human body, probiotics regulate the host's gastrointestinal mucosa and systemic immune function or regulate the balance of intestinal flora, promote nutrient absorption, and maintain intestinal health.

For example, a probiotic crushing device with the authorization announcement number "CN217093762U" has a reasonable and stable structure and combines crushing and screening functions. If the crushing effect is not good, it is convenient to pour the unqualified probiotics on the screen back into the feed hopper. Perform multiple crushing operations to improve work efficiency. However, with this probiotic crushing device, when the probiotics are not completely crushed, since the lower end of the crushing chamber is not blocked, the probiotics may fall directly into the second material tube, which will result in the probiotics in the second material tube not being completely crushed. Grinding requires crushing the probiotics again, which reduces the crushing efficiency of the probiotics. At the same time, in this probiotic crushing device, the probiotic raw materials may adhere to the inner wall of the crushing bin, resulting in less falling of the probiotic raw materials and increasing the working cost of the crushing device.

Utility model content

The purpose of this utility model is to solve the problem that the probiotics fall before being crushed and need to be re-crushed, which reduces the crushing efficiency of the probiotics and the probiotic raw materials may adhere to the inner wall of the crushing bin, resulting in less falling of the probiotic raw materials and increasing the The working cost of the crushing device is a problem, and an efficient crushing device for probiotics is proposed.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

Design a high-efficiency crushing device for probiotics, including a body. The outer wall of the body is provided with a blocking mechanism. The blocking mechanism includes a first motor and a dovetail groove. The outer wall of the first motor is fixedly connected to the body through a bracket. The output shaft of the first motor is fixedly connected to the first bevel gear, the first bevel gear is meshed with the second bevel gear, the outer wall of the second bevel gear is fixedly connected to the gear, and the gear meshes with the rack Connected, the outer wall of the rack is fixedly connected to the baffle plate, and the rack is slidingly connected to the body through a dovetail groove processed on the surface of the body.

Preferably, the upper end of the body is fixedly connected to the housing, and the middle part of the gear is rotatably connected to the body through a pin.

Preferably, a stirring and scraping mechanism is provided inside the casing, and the stirring and scraping mechanism includes a second motor. The outer wall of the second motor is fixedly connected to the inner wall of the casing through a bracket. The output shaft is fixedly connected to the third bevel gear, the third bevel gear is meshed and connected to the fourth bevel gear, the fourth bevel gear is meshed to the fifth bevel gear, and the lower end of the fifth bevel gear is fixed to the transmission rod. The outer wall of the transmission rod is fixedly connected to a plurality of cutting knives, and the output shaft of the second motor is fixedly connected to the two scrapers.

Preferably, the outer walls of the two scrapers penetrate the body and fit with the inner wall of the body, the transmission rod penetrates the body, and the outer wall of the fourth bevel gear is rotationally connected to the body through a pin and a bracket.

Preferably, the surface of the machine body is processed with a feed pipe, and the inner wall of the feed pipe is connected with the inner wall of the machine body.

Preferably, a discharge port is formed at the lower end of the machine body, and an observation window is formed on the outer wall of the machine body.

The utility model proposes an efficient crushing device for probiotics. The beneficial effect is that through the cooperation of the machine body and the material blocking mechanism, the first motor drives the first bevel gear to rotate, the first bevel gear drives the second bevel gear to rotate, and the second bevel gear rotates. The gear drives the gear to rotate, the gear drives the rack to move, and the rack drives the baffle plate to move to block the discharge port. Through the above method, the probiotic raw materials can be prevented from falling without being crushed. There is no need to crush multiple times, thereby improving the crushing device. work efficiency.

Through the cooperation of the housing and the stirring and scraping mechanism, the second motor drives the third bevel gear to rotate, the third bevel gear drives the fourth bevel gear to rotate, the fourth bevel gear drives the fifth bevel gear to rotate, and the fifth bevel gear drives the transmission rod. Rotate, the transmission rod drives the cutting knife to rotate, cutting off the probiotic raw materials, and at the same time, the second motor drives the scraper to rotate, scraping the inner wall of the body. Through the above method, the probiotic raw materials can be prevented from adhering to the inner wall of the body, and the probiotics are increased. The utilization rate of bacterial raw materials is improved, and the working cost of the crushing device is reduced.

Description of drawings

Figure 1 is a schematic structural diagram of the utility model;

Figure 2 is a schematic front cross-sectional view of Figure 1;

Figure 3 is a schematic bottom cross-sectional view of the blocking mechanism in Figure 1;

Figure 4 is a schematic left cross-sectional view of the material blocking mechanism in Figure 1.

In the picture: 1. Machine body, 2. Blocking mechanism, 201. First motor, 202. First bevel gear, 203. Second bevel gear, 204. Rack, 205. Blocking plate, 206. Gear, 207. Dovetail groove, 3. Shell, 4. Stirring and scraping mechanism, 401. Second motor, 402. Third bevel gear, 403. Scraper, 404. Third bevel gear, 405. Fifth bevel gear, 406. Transmission Rod, 407, cutting knife, 5. Feed pipe, 6. Observation window, 7. Discharge port.

Detailed ways

The utility model will be further described below in conjunction with the accompanying drawings:

Referring to the accompanying drawings 1-4: In this embodiment, a high-efficiency crushing device for probiotics includes a body 1. The outer wall of the body 1 is provided with a blocking mechanism 2. The blocking mechanism 2 includes a first motor 201 and a dovetail groove 207. The outer wall of a motor 201 is fixedly connected to the body 1 through a bracket. The body 1 fixes the position of the first motor 201. The size of the first motor 201 is selected according to actual needs and can be selected to meet the working needs. The output shaft of the first motor 201 is connected to the body 1. The first bevel gear 202 is fixedly connected. The first motor 201 drives the first bevel gear 202 to rotate. The first bevel gear 202 is meshed with the second bevel gear 203. The first bevel gear 202 drives the second bevel gear 203 to rotate. The outer wall of the gear 203 is fixedly connected to the gear 206. The second bevel gear 203 drives the gear 206 to rotate. The gear 206 is meshed and connected with the rack 204. The gear 206 drives the rack 204 to move. The outer wall of the rack 204 is fixedly connected to the baffle plate 205. The rack 204 drives the baffle plate 205 to move. The rack 204 is slidingly connected to the body 1 through the dovetail groove 207 processed on the surface of the body 1. The rack 204 slides on the body 1.

Referring to Figure 2: In this embodiment, an efficient crushing device for probiotics is provided. A stirring and scraping mechanism 4 is provided inside the housing 3. The stirring and scraping mechanism 4 includes a second motor 401, and the outer wall of the second motor 401 passes through a bracket. Fixedly connected to the inner wall of the housing 3, the second motor 401 is fixed on the housing 3. The size of the second motor 401 is selected according to actual needs and can be selected to meet the working needs. The output shaft of the second motor 401 and the third bevel gear 402 are fixedly connected, the second motor 401 drives the third bevel gear 402 to rotate, the third bevel gear 402 is meshed with the fourth bevel gear 404, the third bevel gear 402 drives the fourth bevel gear 404 to rotate, the fourth bevel gear 404 is connected with the fourth bevel gear 404. Five bevel gears 405 are meshed and connected. The fourth bevel gear 404 drives the fifth bevel gear 405 to rotate. The lower end of the fifth bevel gear 405 is fixedly connected to the transmission rod 406. The fifth bevel gear 405 drives the transmission rod 406 to rotate. The outer wall of the transmission rod 406 The transmission rod 406 drives the cutting blades 407 to rotate. The output shaft of the second motor 401 is fixedly connected to the two scrapers 403. The second motor 401 drives the scrapers 403 to rotate.

Referring to Figures 1, 2 and 3: In this embodiment, a high-efficiency crushing device for probiotics is provided. The upper end of the body 1 is fixedly connected to the housing 3. The body 1 fixes the position of the housing 3, and the middle part of the gear 206 passes through The pin shaft is rotationally connected to the body 1, the gear 206 rotates on the body 1, the outer walls of the two scrapers 403 penetrate the body 1 and fit with the inner wall of the body 1, the scrapers 403 scrape the body 1, and the transmission rod 406 penetrates the body 1. The outer wall of the fourth bevel gear 404 is rotationally connected to the body 1 through a pin and a bracket. The fourth bevel gear 404 rotates on the body 1. The surface of the body 1 is processed with a feed pipe 5, and the feed pipe 5 is fixed on the body 1. position, the inner wall of the feed pipe 5 is connected with the inner wall of the machine body 1, the lower end of the machine body 1 is processed with a discharge port 7, and the outer wall of the machine body 1 is processed with an observation window 6.

working principle:

When using this high-efficiency crushing device for probiotics, first connect the external power supply of the first motor 201 and start the first motor 201. The first motor 201 drives the first bevel gear 202 to rotate, and the first bevel gear 202 drives the second bevel gear 203. Rotate, the second bevel gear 203 drives the gear 206 to rotate, the gear 206 drives the rack 204 to move, the rack 204 drives the baffle 205 to move, blocking the discharge port 7, and then the probiotic raw materials enter the body through the feed pipe 5 Within 1, then connect the external power supply of the second motor 401 and start the second motor 401. The second motor 401 drives the third bevel gear 402 to rotate, the third bevel gear 402 drives the fourth bevel gear 404 to rotate, and the fourth bevel gear 404 The fifth bevel gear 405 is driven to rotate. The fifth bevel gear 405 drives the transmission rod 406 to rotate. The transmission rod 406 drives the cutting knife 407 to rotate to cut off the probiotic raw materials. At the same time, the second motor 401 drives the scraper 403 to rotate, thereby cutting the body 1 The inner wall is scraped to prevent the probiotic raw materials from adhering to the inner wall of the body 1. The operator observes the situation inside the body 1 through the observation window 6. After the stirring is completed, the first motor 201 continues to work, and the baffle plate 205 is moved through the above method. Far away from the discharge port 7, the crushed probiotic raw materials are sent out of the body 1 from the discharge port 7, thereby completing the efficient crushing process of the probiotics.

Although the present invention has been illustrated and described with reference to preferred embodiments, it will be understood by those of ordinary skill in the art that various changes in form and details may be made within the scope of the claims.

Claims (6)

1. An efficient crushing device for probiotics, including a body (1), characterized in that: the outer wall of the body (1) is provided with a blocking mechanism (2), and the blocking mechanism (2) includes a first motor ( 201) and dovetail groove (207), the outer wall of the first motor (201) is fixedly connected to the body (1) through a bracket, and the output shaft of the first motor (201) is fixedly connected to the first bevel gear (202) , the first bevel gear (202) is meshed with the second bevel gear (203), the outer wall of the second bevel gear (203) is fixedly connected with the gear (206), the gear (206) is connected with the rack (206) 204) are meshed and connected, the outer wall of the rack (204) is fixedly connected to the baffle plate (205), and the rack (204) slides with the body (1) through the dovetail groove (207) processed on the surface of the body (1) connected. 2. An efficient crushing device for probiotics according to claim 1, characterized in that: the upper end of the body (1) is fixedly connected to the casing (3), and the middle part of the gear (206) is connected to the casing (3) through a pin. The body (1) is connected by rotation. 3. An efficient crushing device for probiotics according to claim 2, characterized in that: a stirring and scraping mechanism (4) is provided inside the housing (3), and the stirring and scraping mechanism (4) includes A second motor (401). The outer wall of the second motor (401) is fixedly connected to the inner wall of the housing (3) through a bracket. The output shaft of the second motor (401) is fixed to the third bevel gear (402). The third bevel gear (402) is meshed and connected with the fourth bevel gear (404), the fourth bevel gear (404) is meshed and connected with the fifth bevel gear (405), and the fifth bevel gear (405) is meshed and connected. ) is fixedly connected to the transmission rod (406), the outer wall of the transmission rod (406) is fixedly connected to a plurality of cutting knives (407), and the output shaft of the second motor (401) is connected to the two scrapers (403 ) are fixedly connected. 4. An efficient crushing device for probiotics according to claim 3, characterized in that: the outer walls of the two scrapers (403) penetrate the body (1) and fit with the inner wall of the body (1), so The transmission rod (406) penetrates the body (1), and the outer wall of the fourth bevel gear (404) is rotationally connected to the body (1) through a pin and a bracket. 5. An efficient crushing device for probiotics according to claim 1, characterized in that: the surface of the body (1) is processed with a feed pipe (5), and the inner wall of the feed pipe (5) is in contact with the machine body. The inner walls of (1) are connected. 6. An efficient crushing device for probiotics according to claim 1, characterized in that: the lower end of the body (1) is processed with a discharge port (7), and the outer wall of the body (1) is processed with an observation window. (6).