CN108949425B - All-round temperature-detecting device of yellow rice wine fermentation process - Google Patents

Abstract

An omnibearing temperature detection device in the yellow wine fermentation process is characterized in that the left end and the right end of a cross beam are coaxially and fixedly sleeved with guide wheels, and groove rings used for being sleeved on the edges of a tank opening of a fermentation tank are arranged on the guide wheels; a driving device for driving the cross beam to rotate on the tank opening of the fermentation tank is arranged on the end head of the left end of the cross beam; a guide rail is arranged below the cross beam, the length direction of the guide rail extends along the axial direction of the cross beam, and the guide rail is positioned between the two guide wheels; a rack extending along the length direction of the guide rail is arranged on the lower surface of the guide rail; the device also comprises a temperature detection part which can move along the length direction of the guide rail and can move up and down to be close to or far away from the bottom of the fermentation tank; the temperature sensor, the first motor, the second motor and the third motor are all connected with the controller; the controller is connected with a display, the temperature sensor transmits the detected temperature information to the controller in real time, and the controller receives, processes and stores the temperature information and transmits the temperature information to the display for displaying.

Description

All-round temperature-detecting device of yellow rice wine fermentation process

Technical Field

The application belongs to the field of detection, and particularly relates to an omnibearing temperature detection device for a yellow wine fermentation process.

Background

The yellow wine is a brewed wine with low grain consumption, low alcohol content and high nutrition, is one of the types of wine advocated to be developed by China, accords with the consumption trend of low alcohol content, nutrition and health care in the wine market, and has wide development prospect.

The most critical process, namely the primary fermentation process, is not needed for mass production of wines. However, the primary fermentation is accompanied by uncertainty influencing factors of parameters such as temperature, alcoholicity and the like, and as the fermentation proceeds, the primary fermentation influences the mouthfeel, the flavor, the quality and the like of the finished yellow wine.

The temperature and the alcohol degree in the process of fermenting the yellow wine are important factors for success or failure of fermenting the yellow wine. Wherein, the harrow opening is difficult to control, and basically the harrow opening is operated on site by an experienced master. The parameters of temperature, alcohol degree and the like are mainly four links of rice soaking, primary fermentation, secondary fermentation and blending. The rice soaking is related to room temperature control; the primary fermentation is in four temperature stages, is complex, and the fermentation time is generally 96 hours; the post fermentation process is generally about 25 days, and the temperature is maintained at 13-15 ℃, so that the control is easy. However, most of the current wine production enterprises still rely on manual measurement methods in the yellow wine fermentation process or use digital measurement equipment manually, and the defects of time and labor waste, small detection range, poor instantaneity and poor systematicness exist.

Disclosure of Invention

The application provides an omnibearing temperature detection device for the yellow wine fermentation process, which aims to overcome the defects of time and labor waste, small detection range, poor instantaneity and poor systematicness of the conventional measurement method for temperature measurement in the yellow wine fermentation process.

The technical scheme adopted by the application is as follows:

the embodiment of the application provides an omnibearing temperature detection device in a yellow wine fermentation process, which comprises a cross beam erected on a fermentation tank opening along the radial direction, wherein guide wheels are coaxially and fixedly sleeved at the left end and the right end of the cross beam, a groove ring used for being sleeved on the edge of the fermentation tank opening is arranged on the guide wheels, and the central axis of the groove ring is coincident with the central axis of the cross beam;

a driving device for driving the cross beam to rotate on the fermentation tank opening is arranged on the end head of the left end of the cross beam, and the driving device comprises a first gear and a first motor; the first gear is fixedly sleeved on the left end of the cross beam; the first motor is fixedly connected with the lower side of the cross beam, an output shaft of the first motor is parallel to the cross beam, a second gear is fixedly sleeved on the output shaft of the first motor, the second gear is positioned under the first gear, and the second gear is meshed with the first gear;

a guide rail is arranged below the cross beam, the length direction of the guide rail extends along the axial direction of the cross beam, and the guide rail is positioned between the two guide wheels; a rack extending along the length direction of the guide rail is arranged on the lower surface of the guide rail;

the device also comprises a temperature detection part which can move along the length direction of the guide rail and can move up and down to be close to or far away from the bottom of the fermentation tank;

the temperature detection part comprises a second motor, the second motor is slidably hung on the guide rail through a sliding block, a third gear is fixedly sleeved on an output shaft of the second motor, and the third gear penetrates through the bottom surface of the sliding block and is meshed with the rack;

the temperature detection part further comprises a third motor, the third motor is fixedly arranged on the lower surface of the second motor, an output shaft of the third motor is parallel to the cross beam, and a pulley is fixedly sleeved on the output shaft of the third motor;

the temperature detection part also comprises a temperature sensor for detecting the temperature in the fermentation tank, and the temperature sensor is connected with the pulley through a traction rope; the lower end of the traction rope is fixedly connected with the temperature sensor, and the upper end of the traction rope is coiled on the pulley;

the device further comprises a controller, wherein the controller is fixed on the right side surface of the third motor; the temperature sensor, the first motor, the second motor and the third motor are all connected with the controller; the controller is connected with a display, the temperature sensor transmits detected temperature information to the controller in real time, and the controller receives, processes and stores the temperature information and transmits the temperature information to the display for display; the controller controls the opening, closing and rotation directions of the first motor, the second motor and the third motor.

Furthermore, the cross beam is cylindrical, so that the cross beam can roll on the opening of the fermentation tank.

Furthermore, the sliding block is curled upwards along the two sides of the length direction of the guide rail to form hook parts capable of being hung on the two sides of the guide rail, and the sliding block is hung on the guide rail through the hook parts.

Further, the first motor is fixed on the end head of the left end of the cross beam through a connecting piece.

The beneficial effects of the application are as follows:

1. when the third motor rotates positively, the third motor drives the pulley to rotate positively, and the pulley continues to coil the traction rope, so that the distance between the temperature sensor and the third motor is shortened, the temperature sensor is far away from the bottom of the fermentation tank, and the temperature of the upper part of the fermentation tank can be measured; on the contrary, when the third motor reverses, the third motor drives the pulley to reverse, so that part of the traction rope fades out from the pulley, the distance between the temperature sensor and the third motor becomes longer, and the temperature sensor is close to the bottom of the fermentation tank, so that the temperature of the lower part of the fermentation tank can be measured. In addition, the second motor moves left and right along the rack, and when the driving device drives the cross beam to move, the position of the temperature sensor on the cross section of the fermentation tank can be indirectly regulated, so that the temperature measurement range of the temperature sensor is regulated in an omnibearing manner, the full-range temperature measurement of the fermentation tank is realized, and the measurement range is large.

2. The temperature sensor detects the temperature in real time, and the display is implemented through the display, so that the real-time performance is good.

3. The controller automatically controls the temperature sensor, the first motor, the second motor, the third motor and the display, so that the system is good, and the use is convenient.

Drawings

FIG. 1 is a schematic diagram of the structure of the present application in one embodiment.

Fig. 2 is a front schematic view of the present application in one embodiment.

Fig. 3 is a schematic view of the structure of the cross beam in one embodiment.

FIG. 4 is a schematic diagram of a guide wheel in an embodiment.

Fig. 5 is a schematic structural diagram of a temperature detecting portion in an embodiment.

Detailed Description

The following description of the embodiments of the present application will be made more apparent and fully hereinafter with reference to the accompanying drawings, in which some, but not all embodiments of the application are shown. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

In the description of the present application, it should be noted that, as the terms "center," "upper," "lower," "left," "right," "vertical," "horizontal," "inner," "outer," and the like are used for convenience in describing the present application and simplifying the description based on the azimuth or positional relationship shown in the drawings, it should not be construed as limiting the present application, but rather should indicate or imply that the devices or elements referred to must have a specific azimuth, be constructed and operated in a specific azimuth. Furthermore, the terms "first," "second," "third," and the like, as used herein, are used for descriptive purposes only and are not to be construed as indicating or implying any relative importance.

In the description of the present application, it should be noted that unless explicitly stated and limited otherwise, the terms "mounted," "connected," and "connected" should be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present application will be understood in specific cases by those of ordinary skill in the art.

Referring to the attached drawings, the application provides an omnibearing temperature detection device for a yellow wine fermentation process, which is characterized in that: the device comprises a cross beam 6 erected on a fermentation tank opening in the radial direction, guide wheels 5 are coaxially and fixedly sleeved at the left end and the right end of the cross beam 6, a groove ring 51 used for being sleeved on the edge of the fermentation tank opening is arranged on the guide wheels 5, and the central axis of the groove ring 51 is coincident with the central axis of the cross beam 6;

specifically, the opening of the fermentation tank is circular. The groove rings 51 are respectively clamped on the edge of the fermenter opening, so that the cross beam 6 is horizontally erected on the fermenter opening along the diameter direction of the fermenter opening.

A driving device for driving the cross beam 6 to rotate on the tank opening of the fermentation tank is arranged on the end head 3 at the left end of the cross beam 6, and the driving device comprises a first gear 4 and a first motor 1; the first gear 4 is fixedly sleeved on the left end of the cross beam 6; the first motor 1 is fixedly connected with the lower side of the cross beam 6, an output shaft of the first motor 1 is parallel to the cross beam 6, a second gear 14 is fixedly sleeved on the output shaft of the first motor 1, the second gear 14 is positioned under the first gear 4, and the second gear 14 is meshed with the first gear 4;

specifically, the first gear 4 is positioned at the left side of the guide wheel 5 on the left end of the cross beam 6; the driving device is positioned outside the tank opening of the fermentation tank.

Specifically, the first motor 1 rotates, the second gear 14 rotates along with the first motor, the second gear 14 drives the cross beam 6 to rotate through the first gear 4, and the cross beam 6 drives the guide wheel 5 to rotate on the tank opening of the fermentation tank, so that the cross beam 6 is driven to move on the tank opening of the fermentation tank.

A guide rail 7 is arranged below the cross beam 6, the length direction of the guide rail 7 extends along the axial direction of the cross beam 6, and the guide rail 7 is positioned between the two guide wheels 5; a rack extending along the length direction of the guide rail 7 is arranged on the lower surface of the guide rail 7;

specifically, the direction along the central axis of the fermenter port is taken as the up-down direction, wherein the direction along the central axis of the fermenter port is taken as the down direction near the fermenter bottom, and the direction along the central axis of the fermenter port is taken as the up direction far away from the fermenter bottom.

The device also comprises a temperature detection part which can move along the length direction of the guide rail 7 and can move up and down to be close to or far away from the bottom of the fermentation tank;

the temperature detection part comprises a second motor 10, the second motor 10 is slidably hung on the guide rail 7 through a sliding block 11, a third gear is fixedly sleeved on an output shaft of the second motor, and the third gear penetrates through the bottom surface of the sliding block 11 and is meshed with the rack;

specifically, the output shaft of the second motor is perpendicular to the cross beam 6.

Specifically, the upper end of the sliding block is slidably hung on the guide rail 7, and the lower end of the sliding block is fixedly connected with the second motor 10. The second motor 10 rotates to drive the third gear to rotate, and the third gear is meshed with the rack, so that the second motor 10 is driven to move left and right along the rack; and when the second motor 10 is rotated forward or backward, the moving direction of the second motor 10 is reversed.

The temperature detection part further comprises a third motor 9, the third motor 9 is fixedly arranged on the lower surface of the second motor 10, an output shaft of the third motor 9 is parallel to the cross beam 6, and a pulley 8 is fixedly sleeved on the output shaft of the third motor 9;

the temperature detection part also comprises a temperature sensor for detecting the temperature in the fermentation tank, and the temperature sensor is connected with the pulley 8 through a traction rope; the lower end of the traction rope is fixedly connected with the temperature sensor, and the upper end of the traction rope is coiled on the pulley 8;

specifically, the pulley 8 is provided with an annular caulking groove along the circumferential direction, the end head at the uppermost end of the traction rope is fixed at the bottom of the annular caulking groove, and the upper end of the traction rope is coiled along the annular caulking groove.

When the third motor 9 rotates positively, the third motor 9 drives the pulley 8 to rotate positively, the pulley 8 continues to coil the traction rope, so that the distance between the temperature sensor and the third motor 9 is shortened, the temperature sensor is far away from the bottom of the fermentation tank, and the temperature of the upper part of the fermentation tank can be measured; on the contrary, when the third motor 9 reverses, the third motor 9 drives the pulley 8 to reverse, so that a part of the traction rope fades out from the pulley 8, the distance between the temperature sensor and the third motor 9 becomes longer, and the temperature sensor is close to the bottom of the fermentation tank, so that the temperature of the lower part of the fermentation tank can be measured.

In addition, the second motor 10 moves left and right along the rack, and when the driving device drives the cross beam 6 to move, the position of the temperature sensor on the cross section of the fermentation tank can be indirectly adjusted, so that the temperature measuring range of the temperature sensor can be adjusted in an omnibearing manner, and the full-range temperature measurement of the fermentation tank can be realized.

The device further comprises a controller 12, said controller 12 being fixed on the right side of said third motor 9; the temperature sensor, the first motor 1, the second motor 10 and the third motor 9 are all connected with the controller; the controller is connected with a display, the temperature sensor transmits detected temperature information to the controller 12 in real time, and the controller 12 receives, processes, stores and transmits the temperature information to the display for display; the controller controls the on, off and rotational directions of the first motor 1, the second motor 10 and the third motor 9.

In particular, the temperature sensor, the first motor 1, the second motor 10 and the third motor 9 and the controller 12 may be connected by wires, but the length of the wires is sufficient to ensure that the temperature sensor is not limited when moving; or, more conveniently, the temperature sensor, the first motor 1, the second motor 10 and the third motor 9 may be in communication connection with the controller through wireless communication such as bluetooth.

Specifically, after the cross beam 6 is erected on the fermenter opening along the diameter direction of the fermenter opening, a controller 12 (on which related operation keys are arranged) controls the opening, closing and rotation directions of the first motor 1, the second motor 10 and the third motor 9 according to a desired temperature detection position, so as to adjust the position of the temperature sensor; the controller 12 then controls the temperature sensor to obtain the desired temperature.

Further, the cross beam 6 is cylindrical, so that the cross beam 6 can roll on the opening of the fermentation tank.

Further, the slider 11 is curled upward along two sides of the length direction of the guide rail 7 to form hooks that can be hung on two sides of the guide rail 7, and the slider 11 is hung on the guide rail 7 through the hooks.

Further, the first motor is fixed on the end head 3 at the left end of the cross beam 6 through the connecting piece 2.

The embodiments described in the present specification are merely examples of implementation forms of the inventive concept, and the scope of protection of the present application should not be construed as being limited to the specific forms set forth in the embodiments, and the scope of protection of the present application and equivalent technical means that can be conceived by those skilled in the art based on the inventive concept.

Claims (4)

1. An all-round temperature-detecting device of yellow rice wine fermentation process, its characterized in that: the device comprises a cross beam erected on the tank opening of the fermentation tank along the radial direction, guide wheels are coaxially and fixedly sleeved at the left end and the right end of the cross beam, a groove ring used for being sleeved on the edge of the tank opening of the fermentation tank is arranged on the guide wheels, and the central axis of the groove ring coincides with the central axis of the cross beam;

a driving device for driving the cross beam to rotate on the fermentation tank opening is arranged on the end head of the left end of the cross beam, and the driving device comprises a first gear and a first motor; the first gear is fixedly sleeved on the left end of the cross beam; the first motor is fixedly connected with the lower side of the cross beam, an output shaft of the first motor is parallel to the cross beam, a second gear is fixedly sleeved on the output shaft of the first motor, the second gear is positioned under the first gear, and the second gear is meshed with the first gear;

a guide rail is arranged below the cross beam, the length direction of the guide rail extends along the axial direction of the cross beam, and the guide rail is positioned between the two guide wheels; a rack extending along the length direction of the guide rail is arranged on the lower surface of the guide rail;

the device also comprises a temperature detection part which can move along the length direction of the guide rail and can move up and down to be close to or far away from the bottom of the fermentation tank;

the temperature detection part comprises a second motor, the second motor is slidably hung on the guide rail through a sliding block, a third gear is fixedly sleeved on an output shaft of the second motor, and the third gear penetrates through the bottom surface of the sliding block and is meshed with the rack;

the temperature detection part further comprises a third motor, the third motor is fixedly arranged on the lower surface of the second motor, an output shaft of the third motor is parallel to the cross beam, and a pulley is fixedly sleeved on the output shaft of the third motor;

the temperature detection part also comprises a temperature sensor for detecting the temperature in the fermentation tank, and the temperature sensor is connected with the pulley through a traction rope; the lower end of the traction rope is fixedly connected with the temperature sensor, and the upper end of the traction rope is coiled on the pulley;

the device further comprises a controller, wherein the controller is fixed on the right side surface of the third motor; the temperature sensor, the first motor, the second motor and the third motor are all connected with the controller; the controller is connected with a display, the temperature sensor transmits detected temperature information to the controller in real time, and the controller receives, processes and stores the temperature information and transmits the temperature information to the display for display; the controller controls the opening, closing and rotation directions of the first motor, the second motor and the third motor.

2. The omnibearing temperature detection device for yellow wine fermentation process as defined in claim 1, wherein: the cross beam is cylindrical, so that the cross beam can roll on the opening of the fermentation tank.

3. The omnibearing temperature detection device for yellow wine fermentation process as defined in claim 1, wherein: the sliding block is curled upwards along the two sides of the length direction of the guide rail to form hook parts capable of being hung on the two sides of the guide rail, and the sliding block is hung on the guide rail through the hook parts.

4. The omnibearing temperature detection device for yellow wine fermentation process as defined in claim 1, wherein: the first motor is fixed on the end head of the left end of the cross beam through a connecting piece.