CN115078641B

CN115078641B - Detection device based on plant sugar content

Info

Publication number: CN115078641B
Application number: CN202210652446.7A
Authority: CN
Inventors: 王硕; 王津; 董璐
Original assignee: Xuzhou Shuotian Biotechnology Co ltd
Current assignee: Xuzhou Shuotian Biotechnology Co ltd
Priority date: 2022-06-07
Filing date: 2022-06-07
Publication date: 2024-10-08
Anticipated expiration: 2042-06-07
Also published as: CN115078641A

Abstract

The invention discloses a detection device based on plant sugar content, which relates to the technical field of auxiliary detection devices of sugar content, and comprises a pressing groove, wherein the cross section of the pressing groove is of a U-shaped structure, the pressing groove is obliquely arranged, and two touch support frames are symmetrically welded at the front and rear parts of the bottom of the pressing groove; two track shafts are symmetrically welded at the bottom of the pressing groove in a left-right mode, a sliding block is sleeved on the two track shafts in a sliding mode, an L-shaped mounting rod is fixedly welded at the right end of the sliding block, and a rolling wheel is rotatably mounted on the L-shaped mounting rod; the rear end of the pressing groove is provided with a plugging structure; the front half section of the left side wall of the squeezing groove is also welded and supported with a six-edge positioning shaft to the left side, and an L-shaped rack is sleeved on the six-edge positioning shaft in a sliding manner through spring pushing. The stress plate is movably arranged in a swinging way, and can swing leftwards to discharge plant scraps crushed and attached on the stress plate from the pressing groove in a one-time overturning way, so that the problem of inconvenience and inefficiency in discharging the plant scraps is solved.

Description

Detection device based on plant sugar content

Technical Field

The invention relates to the technical field of auxiliary detection devices for sugar content, in particular to a detection device based on plant sugar content.

Background

When determining plant sugar degree, generally need roll the stem of plant at first and squeeze juice, then utilize sugar degree measuring apparatu to detect with the juice that squeezes out, current sugar content detection device is owing to lack auxiliary discharge subassembly, most need stretch into the juice container with the finger behind the completion of detection and hold between the fingers the material, need frequently repeat many times hold between the fingers the action and just can accomplish the unloading of all piece, the troublesome operation inefficiency, and although supporting auxiliary discharge subassembly on some devices, mostly need additionally be equipped with driving motor alone for auxiliary discharge subassembly, be unfavorable for reducing cost and the consumption of device.

Disclosure of Invention

The invention aims to provide a plant sugar content-based detection device which is provided with a stress plate, wherein the stress plate is movably installed in a swinging way and can swing leftwards to enable crushed and attached plant scraps to be overturned and discharged from a pressing groove at one time, so that the problem of inconvenience and inefficiency in discharging the plant scraps is solved.

In order to achieve the above purpose, the present invention provides the following technical solutions: the detection device based on the plant sugar content comprises a pressing groove, wherein the cross section of the pressing groove is of a U-shaped structure, the pressing groove is obliquely arranged, and two touch support frames are symmetrically welded at the front and back of the bottom of the pressing groove; two track shafts are symmetrically welded at the bottom of the pressing groove in a left-right mode, a sliding block is sleeved on the two track shafts in a sliding mode, an L-shaped mounting rod is fixedly welded at the right end of the sliding block, and a rolling wheel is rotatably mounted on the L-shaped mounting rod; the rear end of the squeezing groove is of a plugging structure, the front end of the squeezing groove is of an opening structure, a hanging shaft is welded at the front end of the squeezing groove, and a juice receiving cylinder is hung on the hanging shaft; a reciprocating screw rod is rotatably arranged at the middle position of the bottom of the pressing groove, a motor is arranged at the rear end of the pressing groove in a locking and hanging mode, the motor is in shaft connection with the reciprocating screw rod for transmission, and the reciprocating screw rod is in sliding fit with the middle section of the sliding block in a penetrating mode; a stress plate is rotatably arranged on the front half section of the left side wall of the pressing groove and is in swinging, abutting and contacting with the bottom plate of the pressing groove; the front half section of the left side wall of the squeezing groove is also welded and supported with a six-edge positioning shaft to the left side, and an L-shaped rack is sleeved on the six-edge positioning shaft in a sliding manner through spring pushing.

Preferably, a longitudinal positioning shaft is welded and supported on the root section of the six-edge positioning shaft backwards, and the rear end of the longitudinal positioning shaft is welded and fixed with the left side wall of the pressing groove.

Preferably, the bottom of the tail end of the L-shaped rack is rotationally connected with a connecting rod, the tail end of the connecting rod is rotationally provided with a slip ring, and the slip ring is in sliding fit with the longitudinal positioning shaft.

Preferably, the left side of the front end of the stress plate is welded with a U-shaped connecting plate, the tail end of the U-shaped connecting plate is welded and fixed with a rotating shaft, and the rotating shaft is sleeved with a driven gear.

Preferably, a row of tooth plates are arranged at the bottom side of the horizontal part of the L-shaped rack, and the tooth plates on the L-shaped rack are meshed with the driven gear for transmission.

Preferably, six rows of tooth blocks are arranged on the circumferential end surface of the rolling wheel in a surrounding mode, and the rolling wheel is in rolling contact with the stress plate.

Preferably, the left end of the sliding block is welded with an L-shaped pull rod, and the L-shaped pull rod protrudes towards the rear side support.

Preferably, the L-shaped pull rod slides along the sliding block, and the rear vertical support part of the L-shaped pull rod slides forwards to be in abutting contact with the tail end section of the connecting rod.

Preferably, the length of the stress plate is four fifths of the length of the pressing groove, and the front end of the stress plate is not covered on the bottom plate of the pressing groove.

Preferably, a rectangular groove is formed in the front half section of the left side wall of the pressing groove and close to the six-edge positioning shaft, and a vertical supporting support plate on the U-shaped connecting plate and close to the pressing groove is in swing and plug-in connection with the rectangular groove.

Compared with the prior art, the invention has the beneficial effects that:

1. according to the invention, the stress plate is movably arranged in a swinging way, and can swing leftwards to discharge plant scraps crushed and attached on the stress plate from the pressing groove in a one-time overturning way, so that compared with a traditional detection device for carrying out discharge by taking and pinching the plant scraps in the pressing container by fingers, the plant scraps can be discharged more conveniently and efficiently;

2. According to the invention, through the power transmission of the L-shaped pull rod, when the sliding block slides forwards to drive the rolling wheel to roll the plant to squeeze juice, the sliding ring at the tail end of the linkage pushing connecting rod slides forwards to provide a left-turning unloading driving force for the stress plate, and the spring on the six-edge positioning shaft can push to drive the L-shaped rack to slide back and reset to provide a right-turning resetting driving force for the stress plate, so that a driving motor for providing left-right turning unloading for the stress plate is omitted, the whole power consumption and the whole manufacturing cost of the device are reduced, in addition, the trouble of manually turning the stress plate can be avoided, and time and labor are saved;

3. According to the invention, the rectangular groove provides a swinging space for the U-shaped connecting plate, and the U-shaped connecting plate can plug the rectangular groove in an inserting way in the juice squeezing process, so that the squeezed juice is prevented from flowing out of the rectangular groove.

Drawings

FIG. 1 is a schematic view of a press vat according to the present invention;

FIG. 2 is a schematic view of the right side structure of the press tank of the present invention;

FIG. 3 is a schematic view showing the bottom structure of the press tank of the present invention;

FIG. 4 is a schematic view of the structure of the roller of the present invention;

FIG. 5 shows the stress of the present invention a schematic diagram of a plate structure;

FIG. 6 is a schematic view of a U-shaped connecting plate according to the present invention;

FIG. 7 is a schematic view of the structure of the L-shaped rack of the present invention;

FIG. 8 is an enlarged schematic view of the portion A of FIG. 3 according to the present invention;

In the figure, the correspondence between the component names and the drawing numbers is:

1. A press tank; 101. a longitudinal positioning shaft; 102. a six-edge positioning shaft; 103. a rail shaft; 104. a reciprocating screw; 105. hanging shaft; 2. a force-bearing plate; 201. a U-shaped connecting plate; 202. a driven gear; 3. a juice receiving cylinder; 4. a sliding block; 401. a rolling wheel; 402. an L-shaped pull rod; 5. an L-shaped rack; 501. and a connecting rod.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments.

Referring to fig. 1 to 8, an embodiment of the present invention provides: the utility model provides a detection device based on plant sugar content, includes squeeze groove 1, squeeze groove 1's cross-section is the U column structure, and squeeze groove 1 is the slope and arranges, squeeze groove 1's bottom is the front and back symmetry and welds two place ground contact braced frames, squeeze groove 1 is used for splendid attire plant to be detected, and the plant that awaits measuring is held in atress board 2's top in essence; two track shafts 103 are symmetrically welded at the bottom of the pressing groove 1 in a left-right mode, a sliding block 4 is sleeved on the two track shafts 103 in a sliding mode, an L-shaped mounting rod is fixedly welded at the right end of the sliding block 4, and a rolling wheel 401 is rotatably mounted on the L-shaped mounting rod; the rear end of the squeezing groove 1 is of a plugging structure, the front end of the squeezing groove 1 is of an opening structure, a hanging shaft 105 is welded at the front end of the squeezing groove 1, and a juice receiving cylinder 3 is hooked on the hanging shaft 105; a reciprocating screw rod 104 is rotatably arranged at the middle position of the bottom of the pressing groove 1, a motor is arranged at the rear end of the pressing groove 1 in a locking and hanging manner, the motor is in shaft connection with the reciprocating screw rod 104 for transmission, and the reciprocating screw rod 104 is in penetrating sliding fit with the middle section of the sliding block 4; a stress plate 2 is rotatably arranged on the front half section of the left side wall of the pressing groove 1, and the stress plate 2 is in swinging, abutting and contacting with the bottom plate of the pressing groove 1; a six-edge positioning shaft 102 is welded and supported on the left side of the front half section of the left side wall of the pressing groove 1, an L-shaped rack 5 is sleeved on the six-edge positioning shaft 102 through spring pushing sliding, a motor can rotate to drive a sliding block 4 to slide back and forth in a reciprocating manner through a reciprocating screw 104, the sliding block 4 can drive a rolling wheel 401 to roll and crush plants placed in the pressing groove 1 for juice squeezing, and the pressed juice can flow down and be discharged into a juice receiving barrel 3 as the pressing groove 1 is obliquely supported; six rows of tooth blocks are circumferentially arranged on the circumferential end surface of the rolling wheel 401, and the rolling wheel 401 is in rolling contact with the stress plate 2; an L-shaped pull rod 402 is welded at the left end of the sliding block 4, and the L-shaped pull rod 402 supports and protrudes towards the rear side; the length of the stress plate 2 is four fifths of the length of the pressing groove 1, and the front end of the stress plate 2 is not covered on the bottom plate of the pressing groove 1; the root section of the six-edge positioning shaft 102 is welded and supported with a longitudinal positioning shaft 101, and the rear end of the longitudinal positioning shaft 101 is welded and fixed with the left side wall of the pressing groove 1.

As shown in fig. 7, a connecting rod 501 is rotatably connected to the bottom of the tail end of the L-shaped rack 5, a slip ring is rotatably mounted at the tail end of the connecting rod 501, and is in sliding fit with the longitudinal positioning shaft 101, and the connecting rod 501, the L-shaped rack 5 and the slip ring at the tail end of the connecting rod 501 are jointly connected to form a slider-crank mechanism, by which the slip ring can slide back and forth to drive the L-shaped rack 5 to slide left and right.

As shown in fig. 2, a U-shaped connecting plate 201 is welded on the left side of the front end of the stress plate 2, a rotating shaft is welded and fixed on the tail end of the U-shaped connecting plate 201, a driven gear 202 is sleeved on the rotating shaft, the stress plate 2 is movably installed in a swinging way, and can swing leftwards to discharge plant scraps crushed and attached on the stress plate from the squeezing tank 1 in a one-time overturning way.

As shown in fig. 8, a row of tooth plates are arranged at the bottom side of the horizontal part of the L-shaped rack 5, the tooth plates on the L-shaped rack 5 are meshed with the driven gear 202 for transmission, and the L-shaped rack 5 can slide left and right to be meshed to drive the driven gear 202 and the stress plate 2 to swing, open and close for discharging.

As shown in fig. 8, the L-shaped pull rod 402 slides along the sliding block 4, and the rear end vertical supporting portion of the L-shaped pull rod 402 slides forward to be in abutting contact with the tail end section of the connecting rod 501, through the power transmission of the L-shaped pull rod 402, the sliding block 4 can be linked to push the sliding ring at the tail end of the connecting rod 501 to slide forward to provide the driving force for turning left and unloading for the stressed plate 2 when the rolling wheel 401 rolls plant juice, and the spring on the six-edge positioning shaft 102 can push the L-shaped rack 5 to slide back and reset to provide the driving force for turning right and resetting for the stressed plate 2, so that the driving motor for turning left and right and unloading for the stressed plate 2 is omitted, the whole power consumption and cost of the device are reduced, and the trouble of manually turning the stressed plate 2 can be avoided, and time and labor are saved.

As shown in fig. 1, a rectangular groove is formed in the front half section of the left side wall of the pressing groove 1 near the six-edge positioning shaft 102, a vertical support plate on the U-shaped connecting plate 201 near the pressing groove 1 is in swing-plug fit with the rectangular groove, the rectangular groove provides a swing space for the U-shaped connecting plate 201, the U-shaped connecting plate 201 can plug the rectangular groove in a plug manner in the juice squeezing process, and juice squeezed out of the rectangular groove is prevented from flowing out.

Working principle: when the juice collecting device is used, firstly, plants to be detected are placed in a squeezing groove 1, the plants are placed at the top ends of stress plates 2, then, a motor is started, through a reciprocating screw 104, the motor can rotate to drive a sliding block 4 to slide back and forth, the sliding block 4 can drive a squeezing wheel 401 to roll and crush the plants placed in the squeezing groove 1 to squeeze juice, and as the squeezing groove 1 is arranged in an inclined support manner, the squeezed juice can flow in a juice collecting cylinder 3, and finally, the juice collecting cylinder 3 is taken down to implement detection by a sugar degree detection instrument;

In addition, the stress plate 2 is movably installed in a swinging way, plant scraps attached to the stress plate can be crushed and discharged from the pressing groove 1 in a one-time overturning way by swinging leftwards, and through the power transmission of the L-shaped pull rod 402, the sliding block 4 can be linked to push the sliding ring at the tail end of the connecting rod 501 to slide forwards to provide a driving force for the stress plate 2 to turn left and discharge materials when the rolling wheel 401 rolls plant juice, and the spring on the six-edge positioning shaft 102 can push the L-shaped rack 5 to slide back and reset to provide a driving force for the stress plate 2 to turn right and reset.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims

1. Detection device based on plant sugar content, its characterized in that: the detection device comprises a pressing groove (1), wherein the cross section of the pressing groove (1) is of a U-shaped structure, the pressing groove (1) is obliquely arranged, and two contact support frames are symmetrically welded at the front and back of the bottom of the pressing groove (1); two track shafts (103) are symmetrically welded at the bottom of the pressing groove (1) in a left-right symmetry manner, a sliding block (4) is sleeved on the two track shafts (103) in a sliding manner, an L-shaped mounting rod is fixedly welded at the right end of the sliding block (4), and a rolling wheel (401) is rotatably mounted on the L-shaped mounting rod; the rear end of the squeezing groove (1) is of a plugging structure, the front end of the squeezing groove is of an opening structure, a hanging shaft (105) is welded at the front end of the squeezing groove (1), and a juice receiving cylinder (3) is hooked on the hanging shaft (105); a reciprocating screw (104) is rotatably arranged at the middle position of the bottom of the pressing groove (1), a motor is locked and hung at the rear end of the pressing groove (1), the motor is in shaft connection with the reciprocating screw (104) for transmission, and the reciprocating screw (104) is in sliding fit with the middle section of the sliding block (4) in a penetrating way; a stress plate (2) is rotatably arranged on the front half section of the left side wall of the pressing groove (1), and the stress plate (2) is in swinging abutting contact with the bottom plate of the pressing groove (1); a six-edge positioning shaft (102) is welded and supported to the left side on the front half section of the left side wall of the pressing groove (1), and an L-shaped rack (5) is sleeved on the six-edge positioning shaft (102) in a sliding manner through spring pushing;

a longitudinal positioning shaft (101) is welded and supported on the root section of the six-edge positioning shaft (102) backwards, and the rear end of the longitudinal positioning shaft (101) is welded and fixed with the left side wall of the pressing groove (1);

The bottom of the tail end of the L-shaped rack (5) is rotationally connected with a connecting rod (501), the tail end of the connecting rod (501) is rotationally provided with a slip ring, and the slip ring is in sliding fit with the longitudinal positioning shaft (101);

A U-shaped connecting plate (201) is welded on the left side of the front end of the stress plate (2), a rotating shaft is welded and fixed at the tail end of the U-shaped connecting plate (201), and a driven gear (202) is sleeved on the rotating shaft;

a row of tooth plates are arranged at the bottom side of the horizontal part of the L-shaped rack (5), and the tooth plates on the L-shaped rack (5) are meshed with a driven gear (202) for transmission;

an L-shaped pull rod (402) is welded at the left end of the sliding block (4), and the L-shaped pull rod (402) protrudes towards the rear side support;

The L-shaped pull rod (402) slides along the sliding block (4), and the rear vertical supporting part of the L-shaped pull rod (402) slides forwards to be in abutting contact with the tail end section of the connecting rod (501).

2. The plant sugar content-based detection device according to claim 1, wherein: six rows of tooth blocks are circumferentially arranged on the circumferential end face of the rolling wheel (401), and the rolling wheel (401) is in rolling contact with the stress plate (2).

3. The plant sugar content-based detection device according to claim 1, wherein: the length of the stress plate (2) is four fifths of the length of the pressing groove (1), and the front end of the stress plate (2) is not covered on the bottom plate of the pressing groove (1).

4. The plant sugar content-based detection device according to claim 1, wherein: a rectangular groove is formed in the front half section of the left side wall of the pressing groove (1) and close to the six-edge positioning shaft (102), and a vertical supporting support plate on the U-shaped connecting plate (201) and close to the pressing groove (1) is in swing and plug-in connection with the rectangular groove.