阅读说明：本技术 一种球磨罐及用于土壤样品制备的行星式球磨机 (Ball-milling jar and be used for planetary ball mill of soil sample preparation ) 是由 程家蓉 王丽娟 牛晓东 邓小红 于 2021-08-24 设计创作，主要内容包括：本发明属于环境化学技术领域,提供了一种球磨罐,包括：第一罐体,其具有球磨腔,球磨腔的一端开口；密封盖,第一罐体的一侧设置有插口、另一侧设置有与插口相对应的插槽,密封盖通过插口和插槽与第一罐体可拆卸连接；第二罐体,其具有样品腔,样品腔的一端开口,密封盖的上侧和/或下侧设置有第一限位槽,第二罐体的开口端设置有与第一限位槽相适应的第一限位部；以及过滤筛组件,其通过插口和插槽与第一罐体可拆卸连接；还提供了一种用于土壤样品制备的行星式球磨机包括转盘和设置在转盘上的多个罐体固定装置,还包括上述的球磨罐。本发明所提供的球磨罐及用于土壤样品制备的行星式球磨机,结构简单,便于操作,工作效率较高。(The invention belongs to the technical field of environmental chemistry, and provides a ball milling tank, which comprises: the first tank body is provided with a ball grinding cavity, and one end of the ball grinding cavity is opened; the sealing cover is detachably connected with the first tank body through the socket and the slot; the second tank body is provided with a sample cavity, one end of the sample cavity is opened, the upper side and/or the lower side of the sealing cover is/are provided with a first limiting groove, and the opening end of the second tank body is provided with a first limiting part matched with the first limiting groove; the filter screen assembly is detachably connected with the first tank body through the socket and the slot; the planetary ball mill for preparing the soil sample comprises a rotating disc, a plurality of tank body fixing devices arranged on the rotating disc and the ball milling tank. The ball milling tank and the planetary ball mill for preparing the soil sample, which are provided by the invention, have the advantages of simple structure, convenience in operation and higher working efficiency.)

1. A ball milling jar which characterized in that: the method comprises the following steps:

the ball mill comprises a first tank body, a second tank body and a third tank body, wherein the first tank body is provided with a hollow ball mill cavity, and one end of the ball mill cavity is opened;

a socket is arranged on one side of the first tank body, a slot corresponding to the socket is arranged on the other side of the first tank body, and the sealing cover is detachably connected with the first tank body through the socket and the slot;

the second tank body is provided with a hollow sample cavity, one end of the sample cavity is opened, the upper side and/or the lower side of the sealing cover is/are provided with a first limiting groove, and the opening end of the second tank body is provided with a first limiting part matched with the first limiting groove; and

the filtering screen assembly is detachably connected with the first tank body through the insertion slot and the insertion socket.

2. The ball mill pot of claim 1, wherein: the filter screen assembly includes:

the mounting frame is provided with a mounting hole, and the upper side and/or the lower side of the mounting frame are/is provided with second limiting grooves matched with the first limiting parts; and

and the screen body is provided with a plurality of screen holes and is arranged in the mounting hole.

3. The ball mill pot of claim 2, wherein: the inner wall of mounting hole is provided with first spout, be provided with a plurality of guide posts in the first spout, the screen frame passes through first spout with the guide post with the installing frame sliding connection.

4. The ball mill pot of claim 3, wherein: the filter screen assembly further comprises two vibrating springs, and any one of the two vibrating springs is arranged on the guide column and is arranged on two sides of the screen body respectively.

5. The ball mill pot of claim 3, wherein: and shielding parts are arranged on the upper side and the lower side of the screen body and are matched with the mounting holes.

6. The ball mill pot of claim 5, wherein: and second limiting parts are arranged on the upper side and the lower side of the first sliding groove.

7. The ball milling jar of any one of claims 1 to 6, wherein: further comprising:

the scraper is matched with the sample cavity, is arranged in the second tank body in a sliding manner, is internally provided with a guide rod, and is provided with a guide hole matched with the guide rod;

the lead screw is rotatably arranged in the second tank body;

the ball nut is in threaded connection with the lead screw, and the scraper is fixedly connected with the ball nut;

a first bevel gear is arranged at one end, far away from the opening, of the second tank body, and the first bevel gear is rotatably arranged in the first mounting cavity through a transmission shaft;

the second bevel gear is rotatably arranged in the first mounting cavity and meshed with the first bevel gear, and the second bevel gear is fixedly connected with the lead screw; and

and the knob is arranged on one side of the second tank body and is in transmission connection with the transmission shaft.

8. The ball mill pot of claim 7, wherein: further comprising:

the third bevel gear is matched with the first bevel gear, is arranged opposite to the first bevel gear and is meshed with the first bevel gear, and is rotationally connected with the transmission shaft; and

and the balance piece is arranged on one side of the second tank body, which is far away from the knob, and is fixedly connected with the second tank body.

9. A planetary ball mill for soil sample preparation, includes the carousel and sets up a plurality of jar body fixing device on the carousel, its characterized in that: further comprising a ball mill pot according to any of claims 1 to 8.

10. Planetary ball mill for soil sample preparation according to claim 9, characterized in that: jar body fixing device includes:

the tray is arranged on the turntable, a second mounting cavity is arranged in the tray, a first support and a second support are oppositely arranged at the top of the tray, one opposite sides of the first support and the second support are adapted to the outer wall of the ball milling tank, and the heights of the first support and the second support are lower than that of the ball milling tank;

a tensioning mechanism disposed in the second mounting cavity;

a first end of the locking belt is connected to the inner side wall of the second mounting cavity, and a second end of the locking belt passes through the first support after passing through the tensioning mechanism;

a locking buckle assembly disposed at the second end of the locking strap; and

the locking mechanism is arranged on the second support and used for locking the locking assembly after the locking belt bypasses the top of the ball milling tank;

when the turntable rotates, the tensioning mechanism applies reverse acting force to the free end of the locking belt under the action of centrifugal force so as to further tighten the locking belt.

Technical Field

The invention relates to the technical field of environmental chemistry, in particular to a ball milling tank and a planetary ball mill for preparing a soil sample.

Background

In the preparation process of soil samples, it is generally required to prepare samples that are sieved through a ten-mesh sieve, sieved through a sixty-mesh sieve and sieved through a hundred-mesh sieve. When preparing samples which are sieved by sixty meshes and hundreds meshes, the soil samples are usually repeatedly ground by using a planetary ball mill to achieve the aim of sieving by sixty meshes or hundreds meshes. However, when the existing ball mill is used for grinding, after each grinding, the materials and grinding balls in the ball mill tank are firstly poured out and loaded into the corresponding sieve, for example: when preparing a sample which is sieved by a sixty-mesh sieve, the grinding balls and the materials are poured into the sixty-mesh sieve, and when preparing a sample which is sieved by a hundred-mesh sieve, the grinding balls and the materials are poured into the hundred-mesh sieve; the sieve is then placed on a shaker to shake to sift out acceptable samples, and so on until all samples pass through the sieve.

The ball mill has the following defects: the operation is complex and the efficiency is low.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide a ball milling tank and a planetary ball mill for preparing a soil sample, which are simple to operate and improve the efficiency.

In order to achieve the above object, the present invention provides in one aspect a ball milling jar comprising:

the ball mill comprises a first tank body, a second tank body and a third tank body, wherein the first tank body is provided with a hollow ball mill cavity, and one end of the ball mill cavity is opened;

a socket is arranged on one side of the first tank body, a slot corresponding to the socket is arranged on the other side of the first tank body, and the sealing cover is detachably connected with the first tank body through the socket and the slot;

the second tank body is provided with a hollow sample cavity, one end of the sample cavity is opened, the upper side and/or the lower side of the sealing cover is/are provided with a first limiting groove, and the opening end of the second tank body is provided with a first limiting part matched with the first limiting groove; and

the filtering screen assembly is detachably connected with the first tank body through the insertion slot and the insertion socket.

Further, the filter screen assembly comprises:

the mounting frame is provided with a mounting hole, and the upper side and/or the lower side of the mounting frame are/is provided with second limiting grooves matched with the first limiting parts; and

and the screen body is provided with a plurality of screen holes and is arranged in the mounting hole.

Further, the inner wall of mounting hole is provided with first spout, be provided with a plurality of guide posts in the first spout, the screen frame passes through first spout with the guide post with the installing frame sliding connection.

Further, the filter screen assembly further comprises two vibration springs, wherein the two vibration springs are arranged on any one of the guide columns and are respectively arranged on two sides of the screen body.

Furthermore, the upper side and the lower side of the screen body are provided with shielding parts, and the shielding parts are adaptive to the mounting holes.

Furthermore, the upper side and the lower side of the first sliding groove are provided with second limiting parts.

Further, still include:

the scraper is matched with the sample cavity, is arranged in the second tank body in a sliding manner, is internally provided with a guide rod, and is provided with a guide hole matched with the guide rod;

the lead screw is rotatably arranged in the second tank body;

the ball nut is in threaded connection with the lead screw, and the scraper is fixedly connected with the ball nut;

a first bevel gear is arranged at one end, far away from the opening, of the second tank body, and the first bevel gear is rotatably arranged in the first mounting cavity through a transmission shaft;

the second bevel gear is rotatably arranged in the first mounting cavity and meshed with the first bevel gear, and the second bevel gear is fixedly connected with the lead screw; and

and the knob is arranged on one side of the second tank body and is in transmission connection with the transmission shaft.

Further, still include:

the third bevel gear is matched with the first bevel gear, is arranged opposite to the first bevel gear and is meshed with the first bevel gear, and is rotationally connected with the transmission shaft; and

and the balance piece is arranged on one side of the second tank body, which is far away from the knob, and is fixedly connected with the second tank body.

In another aspect, the present invention provides a planetary ball mill for soil sample preparation comprising the above-described ball mill pot.

Further, the tank fixing device includes:

the tray is arranged on the turntable, a second mounting cavity is arranged in the tray, a first support and a second support are oppositely arranged at the top of the tray, one opposite sides of the first support and the second support are adapted to the outer wall of the ball milling tank, and the heights of the first support and the second support are lower than that of the ball milling tank;

a tensioning mechanism disposed in the second mounting cavity;

a first end of the locking belt is connected to the inner side wall of the second mounting cavity, and a second end of the locking belt passes through the first support after passing through the tensioning mechanism;

a locking buckle assembly disposed at the second end of the locking strap; and

the locking mechanism is arranged on the second support and used for locking the locking assembly after the locking belt bypasses the top of the ball milling tank;

when the turntable rotates, the tensioning mechanism applies reverse acting force to the free end of the locking belt under the action of centrifugal force so as to further tighten the locking belt.

The invention has the beneficial effects that:

according to the ball milling tank and the planetary ball mill for preparing the soil sample, the first tank body, the second tank body, the sealing cover and the filter screen assembly are arranged, so that the soil sample can be screened without pouring out the soil sample and the grinding balls after the ball milling is finished, the operation is simple, and the working efficiency is improved.

Drawings

In order to more clearly illustrate the detailed description of the invention or the technical solutions in the prior art, the drawings that are needed in the detailed description of the invention or the prior art will be briefly described below. Throughout the drawings, like elements or portions are generally identified by like reference numerals. In the drawings, elements or portions are not necessarily drawn to scale.

FIG. 1 is a perspective view of a ball milling jar according to one embodiment of the present invention;

FIG. 2 is a cross-sectional view of the ball milling jar of FIG. 1 during milling;

FIG. 3 is a cross-sectional view of the milling jar of FIG. 1 during sieving;

FIG. 4 is an enlarged view taken at A of FIG. 2;

FIG. 5 is an enlarged view at B shown in FIG. 2;

FIG. 6 is an enlarged view at C shown in FIG. 2;

FIG. 7 is an enlarged view at D of FIG. 2;

FIG. 8 is an enlarged view at E shown in FIG. 3;

FIG. 9 is a perspective view of a fixing device for a bowl of a ball mill according to the present invention;

FIG. 10 is a cross-sectional view of the can body securing apparatus shown in FIG. 9;

FIG. 11 is an enlarged view at F of FIG. 9;

FIG. 12 is an enlarged view at G of FIG. 9;

FIG. 13 is an enlarged view taken at H of FIG. 10;

FIG. 14 is a transverse cross-sectional view of the tray shown in FIG. 9;

fig. 15 is a structural view of the locking piece locked by the latch.

Reference numerals:

100-first tank body, 110-ball grinding cavity, 120-socket, 130-slot, 140-positioning block, 200-sealing cover, 210-first limiting groove, 300-second tank body, 301-sample cavity, 302-first limiting part, 303-guide rod, 304-first mounting cavity, 305-limiting groove, 310-scraper, 320-lead screw, 330-ball nut, 340-first bevel gear, 350-second bevel gear, 360-knob, 370-transmission shaft, 380-third bevel gear, 390-balancing part, 400-filter screen component, 410-mounting frame, 411-mounting hole, 412-second limiting groove, 413-first chute, 414-guide column, 415-second limiting part, 420-screen body, 421-a shielding part, 430-a vibrating spring, 500-a tray, 510-a second installation cavity, 520-a belt outlet hole, 530-a second sliding groove, 540-an accommodating groove, 550-a fixed guide roller, 560-a first support, 561-a belt outlet channel, 570-a second support, 571-a lock hole, 572-a first chamber, 573-a second chamber, 574-a third sliding groove, 580-a positioning seat, 581-a positioning groove, 600-a tensioning mechanism, 610-a first sliding block, 620-a connecting piece, 630-a movable guide roller, 640-a first return spring, 700-a locking belt, 800-a locking assembly, 810-a limiting plate, 820-a locking block, 821-a clamping groove, 822-a pushing part, 900-a locking mechanism, 910-a locking unit, 911-clamping block, 912-stop block, 913-sliding rod, 914-second return spring, 920-driving component, 921-driving plate and 922-pin column.

Detailed Description

Embodiments of the present invention will be described in detail below with reference to the accompanying drawings. The following examples are only for illustrating the technical solutions of the present invention more clearly, and therefore are only examples, and the protection scope of the present invention is not limited thereby.

It is to be noted that, unless otherwise specified, technical or scientific terms used herein shall have the ordinary meaning as understood by those skilled in the art to which the invention pertains.

In the description of the present application, it is to be understood that the terms "central," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," "axial," "radial," "circumferential," and the like are used in the orientations and positional relationships indicated in the drawings for convenience in describing the invention and to simplify the description, and are not intended to indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and are therefore not to be considered limiting of the invention.

Furthermore, the terms "first", "second", etc. are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. In the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

In this application, unless expressly stated or limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can include, for example, fixed connections, removable connections, or integral parts; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In this application, unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may be directly contacting the first and second features or indirectly contacting the first and second features through intervening media. Also, a first feature "on," "over," and "above" a second feature may be directly or diagonally above the second feature, or may simply indicate that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature may be directly under or obliquely under the first feature, or may simply mean that the first feature is at a lesser elevation than the second feature.

As shown in fig. 1 to 8, the present invention provides a ball milling jar comprising a first jar body 100, a sealing lid 200, a second jar body 300, and a filter screen assembly 400.

The first tank 100 has a hollow ball milling chamber 110, and one end of the ball milling chamber 110 is open. The first tank 100 has a socket 120 formed at one side thereof and a socket 130 formed at the other side thereof corresponding to the socket 120. Specifically, the socket 120 and the slot 130 are semicircular, and the slot 130 is opened at the inner side of the first tank 100 and communicates with the socket 120.

The sealing cap 200 is detachably coupled to the first tank 100 through the socket 120 and the insertion groove 130. Specifically, the sealing cap 200 has an outer diameter at one side of the socket 120 corresponding to that of the first can 100 and an outer diameter at one side of the socket 130 corresponding to that of the socket 130. When the sealing cover 200 is used, the sealing cover 200 is inserted into the first tank 100 from the insertion opening 120, and the movement of the sealing cover 200 in the vertical direction is limited under the action of the insertion opening 120 and the insertion groove 130.

The second canister 300 has a hollow sample chamber 301, one end of the sample chamber 301 is open, the upper side and/or the lower side of the sealing cap 200 is provided with a first limiting groove 210, and the open end of the second canister 300 is provided with a first limiting portion 302 adapted to the first limiting groove 210. Preferably, the outer diameter of the first limiting portion 302 is adapted to the inner diameter of the first tank 100 so as to limit the second tank 300, and the upper and lower sides of the sealing cover 200 are both provided with first limiting grooves 210 so as to avoid distinguishing the front and back sides when in use. When the sealing cover 200 is used, the end of the second tank 300, at which the first limiting portion 302 is provided, is inserted into the first tank 100, and the first limiting portion 302 is inserted into the first limiting groove 210, so that the movement of the sealing cover 200 in the horizontal direction is limited.

The filter screen assembly 400 is removably connected to the first tank 100 via the socket 120 and the slot 130. Specifically, the filter screen assembly 400 has an outer diameter on one side of the socket 120 corresponding to the outer diameter of the first tank 100 and an outer diameter on one side of the socket 130 corresponding to the outer diameter of the socket 130. During the use, after once ball-milling is accomplished, at first extract sealed lid 200, then insert corresponding filter sieve subassembly 400 in first jar body 100 through socket 120, specifically, when preparing the sample of sixty mesh sieve, just insert filter sieve subassembly 400 that the sieve mesh is sixty meshes, when preparing the sample of hundred meshes, just insert filter sieve subassembly 400 that the sieve mesh is hundred meshes, later invert the ball-milling jar at the bobbing machine, after fixing the ball-milling jar, start the bobbing machine and vibrate, under the effect of bobbing machine, the soil sample in first jar body 100 will pass through filter sieve subassembly 400 and get into in the second jar body 300 to accomplish the screening to the sample of this time grinding. Then the second tank 300 and the filter sieve assembly 400 are taken down, the sealing cover 200 is inserted, the sample in the second tank 300 is taken out, the second tank 300 is inserted, and the ball milling tank is put into a ball mill for ball milling.

When in use, firstly, a sample to be ground is put into the first tank 100 and a proper amount of grinding balls are put into the first tank; then, the sealing cap 200 is inserted from the insertion opening 120, and then the second can 300 is inserted from the opening of the first can 100; and then, putting the ball milling tank on a ball mill, fixing and then carrying out ball milling.

After the ball milling is completed, firstly, the sealing cover 200 is pulled out and the corresponding filter screen assembly 400 is inserted into the first tank 100 through the socket 120; afterwards, invert the ball-milling jar at the bobbing machine, after fixing the ball-milling jar, start the bobbing machine and vibrate, under the effect of bobbing machine, the soil sample in the first jar body 100 will get into in the second jar body 300 through filter sieve subassembly 400 to the completion is to the screening of this time the sample of grinding.

Then, the second tank 300 and the filter sieve assembly 400 are taken down, the sealing cover 200 is inserted, the sample in the second tank 300 is taken out, the second tank 300 is inserted, and the ball milling tank is put into a ball mill for ball milling.

The above operation is repeated until all of the soil sample has passed through filter screen assembly 400.

According to the ball milling tank provided by the invention, the first tank body 100, the second tank body 300, the sealing cover 200 and the filter screen assembly 400 are arranged, so that a soil sample can be screened without pouring out the soil sample and the grinding balls after ball milling is finished, the operation is simple, and the working efficiency is improved.

In one embodiment, filter screen assembly 400 includes a mounting frame 410 and a screen body 420.

The mounting frame 410 is provided with a mounting hole 411, and specifically, an outer diameter of the mounting frame 410 on one side of the socket 120 is adapted to an outer diameter of the first tank 100, and an outer diameter of the mounting frame 410 on one side of the slot 130 is adapted to an outer diameter of the slot 130. The mounting hole 411 is a through hole and is coaxially formed in the mounting frame 410. The mounting frame 410 is provided with a second limiting groove 412 at the upper side and/or the lower side thereof, wherein the second limiting groove is matched with the first limiting part 302. Preferably, the upper and lower sides of the mounting frame 410 are both provided with second limiting grooves 412, so that the front and the back do not need to be distinguished when the mounting frame is used.

A plurality of screen holes are formed in the screen body 420, and specifically, when the screen body 420 is a hundred-mesh screen, the number of the screen holes is hundred; when the screen body 420 is sixty mesh screen, the number of screen holes is sixty mesh. The screen body 420 is installed in the installation hole 411.

The filter screen assembly 400 of this construction is simple to construct.

In one embodiment, the inner wall of the mounting hole 411 is formed with a first sliding slot 413, and a plurality of guiding posts 414 are fixedly disposed in the first sliding slot 413. Preferably, the guide posts 414 are integrally formed with the mounting frame 410. The screen body 420 is slidably connected to the mounting frame 410 through the first sliding groove 413 and the guide post 414. Specifically, the screen body 420 is provided with a guide hole matching with the guide post 414, and the screen body 420 is slidably connected with the guide post 414 through the guide hole.

During the use, at the in-process that the bobbing machine vibrates the ball-milling jar in order to sieve soil sample, screen frame 420 can reciprocate in installing frame 410 along with the upper and lower vibration of bobbing machine to collide with the vibration effect of reinforcing with installing frame 410 to screen frame 420, thereby improve the efficiency of screening.

This structure is convenient for improve the vibration effect of screen frame 420 to improve screening efficiency.

In one embodiment, the filter screen assembly 400 further includes two vibrating springs 430, and two vibrating springs 430 are sleeved on any one of the guide posts 414, and the two vibrating springs 430 are respectively located at the upper and lower sides of the screen body 420. In the process that the screen body moves up and down in the mounting frame because of the vibrating machine, the vibrating spring 430 can further enhance the frequency of vibration, so that the vibration effect is further enhanced, and the screening efficiency is further improved.

In one embodiment, the screen body 420 is fixedly provided with shielding parts 421 at upper and lower sides thereof, and the shielding parts 421 are adapted to the mounting holes 411. Preferably, the shielding portion 421 is integrally formed with the screen body. During the use, at the in-process that the bobbing machine vibrates the ball-milling jar in order to sieve soil sample, screen frame 420 can reciprocate in installation frame 410 along with the vibration of bobbing machine with reinforcing vibration effect, under the effect of shielding portion 421, prevents that soil sample from getting into in the first spout 413.

With this structure, the soil sample can be prevented from entering the first chute 413.

In one embodiment, the first sliding groove 413 is provided with second limiting portions 415 at upper and lower sides thereof. The second limiting parts 415 are arranged on the upper side and the lower side of the first sliding groove 413, so that the moving distance of the screen body 420 in the mounting frame 410 is limited, and a soil sample is prevented from entering the first sliding groove 413 due to the fact that the moving distance of the screen body 420 is too large.

In one embodiment, a scraper 310, a lead screw 320, a ball nut 330, a first bevel gear 340, a second bevel gear 350, and a knob 360 are also included.

The scraper 310 is adapted to the sample chamber 301, the scraper 310 is slidably mounted in the second canister 300, and the guide rod 303 is fixed in the second canister 300. Specifically, the guide bar 303 is integrally formed with the second tank 300. The scraper 310 is provided with a guide hole matched with the guide rod 303. The lead screw 320 is rotatably installed in the second tank 300. The ball nut 330 is screwed to the screw 320, and the scraper 310 is fixedly connected to the ball nut 330. When the scraper is used, the scraper 310 reciprocates linearly up and down in the second tank 300 by rotating the lead screw 320 and under the action of the structure of the ball lead screw 320. It should be noted here that the structure of the ball screw 320 is a sealed ball screw 320, specifically, the nut pair is sealed by a felt ring, the thickness of the felt ring is 2-3 times of the thread pitch, and the inner hole is made into a threaded shape, so that the felt ring tightly embraces the screw 320 and fits into the manipulation at the two ends of the nut or the sleeve. The sealing ring is made of soft felt, oil-proof rubber or nylon material. These are prior art and will not be described in great detail herein.

The end of the second tank 300 far away from the opening is provided with a first mounting cavity 304, and a first bevel gear 340 is rotatably mounted in the first mounting cavity 304 through a transmission shaft 370. Preferably, the first bevel gear 340 is integrally formed with the drive shaft 370. The second bevel gear 350 is rotatably installed in the first installation cavity 304 and meshed with the first bevel gear 340, and the second bevel gear 350 is fixedly connected with the lead screw 320. Specifically, one end of the lead screw 320 extends into the first mounting cavity 304 and is fixedly connected with the second bevel gear 350. Preferably second bevel gear 350 is integrally formed with lead screw 320.

The knob 360 is rotated at one side of the second tank 300 and is in driving connection with the driving shaft 370. Specifically, the knob 360 is fixedly connected to one end of the transmission shaft 370.

When the scraper is used, the second bevel gear 350 is driven to rotate through the first bevel gear 340 by rotating the knob 360, and the scraper 310 performs reciprocating linear motion up and down in the second tank 300 under the action of the structure of the ball screw 320.

The sample chamber 301 is generally elongate and cylindrical. Thus, it is inconvenient to clean the soil in the sample chamber 301 when in use. Therefore, in this embodiment, when the soil in the sample cavity 301 needs to be cleaned, the knob 360 is rotated, so that the scraper 310 moves towards the direction close to the opening of the sample cavity 301, and in the moving process of the scraper 310, the scraper 310 will scrape the sample on the inner wall of the sample cavity 301 where the scraper moves, and meanwhile, by moving the scraper 310 to the opening end of the sample cavity 301, the depth of the sample cavity 301 is reduced, so that the soil sample in the sample cavity 301 is easier to clean.

This configuration facilitates cleaning of the soil sample within the second tank 300 while facilitating cleaning of the second tank 300.

In one embodiment, a third bevel gear 380 and a counterbalance 390 are also included.

Wherein. The third bevel gear 380 is adapted to the first bevel gear 340, specifically, the third bevel gear 380 and the first bevel gear 340 have the same size and the same mass, the third bevel gear 380 and the first bevel gear 340 are disposed opposite to each other, specifically, the third bevel gear 380 and the first bevel gear 340 are disposed on two sides of the second bevel gear 350 and are both engaged with the first bevel gear 340, and the third bevel gear 380 is rotatably connected to the transmission shaft 370. In use, the first bevel gear 340 drives the second bevel gear 350 to rotate, the second bevel gear 350 drives the third bevel gear 380 to rotate, and the third bevel gear 380 is rotatably connected with the transmission shaft 370, so that the rotation of the third bevel gear 380 and the transmission shaft 370 is not influenced.

The balance member 390 is adapted to the knob 360, and specifically, the balance member 390 has the same size and mass as the knob 360, and the balance member 390 is installed on a side of the second tank 300 away from the knob 360 and is fixedly connected to the second tank 300.

During the use, carry out better support to transmission shaft 370 through setting up third bevel gear 380, simultaneously, set up through third bevel gear 380 and first bevel gear 340 relatively for ball-milling jar is at the in-process of rotation, and inertia distributes more balancedly, rotates more steadily, balanced promptly. Similarly, through setting up balancing piece 390 and balancing with knob 360 for ball-milling jar is at the in-process of pivoted, and the inertia of both sides distributes more balancedly, and the pivoted is more steady.

As shown in fig. 9 to 15, the present invention also provides a planetary ball mill for soil sample preparation, comprising a rotary plate 001 and a plurality of pot body fixing devices mounted on the rotary plate 001, and further comprising the above-mentioned ball mill pot.

In one embodiment, the can body securing apparatus includes a tray 500, a first seat 560, a second seat 570, a tensioning mechanism 600, a locking band 700, a latch assembly 800, and a locking mechanism 900. The tray 500 is installed at the top of carousel 001 and is connected with carousel 001 rotates, has seted up second installation cavity 510 in the tray 500, and the top of tray 500 is provided with first support 560 and second support 570 relatively, and the relative one side of first support 560 and second support 570 suits with the outer wall of ball-milling jar, and the height of first support 560 and second support 570 all is less than the height of ball-milling jar. Preferably, the first and second seats 560, 570 are integrally formed with the tray 500.

The tensioning mechanism 600 is installed in the second installation cavity 510, a first end of the locking belt 700 is fixedly connected with an inner side wall of the second installation cavity 510, and a second end (i.e., a second end) passes through the first support 560 after passing through the tensioning mechanism 600. Specifically, the holding groove 540 has been seted up to the top surface of tray 500, has seted up out foraminiferous 520 on another inside wall of second installation cavity 510, holding groove 540 with go out foraminiferous 520 intercommunication, fixed deflector roll 550 is installed to the holding groove 540 internal rotation, first support 560 is gone up along vertical seting up with the play area passageway 561 of holding groove 540 intercommunication, the locking area 700 that wears out from going out the foraminiferous 520 is walked around fixed deflector roll 550 after stretches out outside first support 560 through going out area passageway 561.

The locking assembly 800 is fixedly connected to the second end of the locking band 700, the locking mechanism 900 is mounted on the second support 570, and the locking mechanism 900 is used to lock the locking assembly 800 after the locking band 700 is passed around the top of the ball mill pot. Preferably, the top of the ball milling jar is opened with a limit groove 305 to limit the locking band 700, thereby better fixing the ball milling jar. Specifically, the limit groove 305 is opened on the second tank 300. Preferably, the both ends of spacing recess are circular-arcly to locking area 700 conduct power better, thereby carry out better fixed to the ball-milling jar, can also avoid ball-milling jar wearing and tearing locking area 700 simultaneously.

In addition, when the turntable 001 rotates, the tensioning mechanism 600 applies an opposite force to the second end of the locking belt 700 under the centrifugal force to further tighten the locking belt 700.

In use, by confining the ball milling bowl between the first seat 560 and the second seat 570, the ball milling bowl is prevented from being displaced along the top surface of the tray 500. And, the locking belt 700 bypasses the limiting groove at the top of the ball mill pot by pulling the locking assembly 800, and the locking assembly 800 is locked by using the locking mechanism 900, and the locking belt 700 can cause the tensioning mechanism 600 to deform to a certain extent in the process of pulling the locking belt 700. When the rotary disc 001 rotates, the whole tank body fixing device can revolve around the axis of the rotary disc 001 and can rotate. Therefore, under the effect of centrifugal force, straining device 600 can exert reverse effort to the second end of locking band 700 to further tighten up locking band 700, make it firmly compress tightly on the ball-milling jar, avoided the ball-milling jar to take place vertical shake.

The planetary ball mill for preparing the soil sample, provided by the invention, abandons the bolt pressure lever mechanism used in the traditional equipment to fix the ball milling tank in the tank body fixing device, so that the operation flow of repeatedly screwing or unscrewing the bolt is omitted, the fixing mode of the ball milling tank is more convenient, and the effective fixation of the ball milling tank is ensured on the premise of improving the speed of assembling and disassembling the ball milling tank, thereby improving the working efficiency and safety of the grinding process in the soil sample preparation.

Specifically, the tensioning mechanism 600 includes two first sliders 610, two links 620, a movable guide roller 630, and two first return springs 640. The second sliding grooves 530 are formed in two opposite inner side walls of the second mounting cavity 510. The two first sliding blocks 610 are respectively slidably mounted in the two second sliding grooves 530, and the two connecting members 620 are respectively fixed to the sidewalls of the two first sliding blocks 610 on opposite sides. Two ends of the movable guide roller 630 are respectively rotatably connected with the two connecting pieces 620, and the locking belt 700 passes through the belt outlet hole 520 after passing around the movable guide roller 630. The two first return springs 640 are respectively disposed to correspond to the two links 620, both ends of the first return springs 640 are respectively connected to the links 620 and the third inner sidewall, and the first return springs have a tendency to move the movable guide roller 630 in a direction away from the exit hole 520 in a natural state.

In use, the first end of the locking band 700 is fixedly connected with the inner side wall of the second mounting cavity 510. Therefore, in the process of pulling the locking band 700, the locking band 700 slides the two first sliders 610 along the second sliding groove 530 by pulling the movable guide roller 630, and finally the first sliders 610 collide with the second sliding groove 530. In the process, the connecting member 620 pulls the first return spring 640 to deform, so as to apply a directional acting force to the locking belt 700, thereby achieving the purpose of locking the ball milling jar. When the planetary ball mill is started, the movable guide roller 630 is moved away from the locking band 700 by centrifugal force, thereby applying a reverse force to the locking band 700 to further tighten the locking band 700 to be firmly pressed against the ball mill pot. It should be noted that when the first sliding block 610 collides with the second sliding chute 530, the movable guide roller 630 is still kept on the side of the axis of the ball milling jar far from the belt outlet hole 520, so as to ensure that the movable guide roller 630 always tightens the locking belt 700 under the centrifugal force.

Specifically, the locking assembly 800 includes a limiting plate 810 and a locking block 820, the limiting plate 810 is installed at the second end of the locking band 700 and abuts against the top of the first support 560, the locking block 820 is installed at one side of the limiting plate 810 departing from the locking band 700, and two clamping grooves 821 are formed in the locking block 820. The top of the second support 570 is recessed downwards to form a locking hole 571, the locking hole 571 is in insertion fit with the locking block 820, and the locking mechanism 900 is used for clamping or loosening the two clamping grooves 821. After the ball milling is finished, the locking mechanism 900 is operated to loosen the locking block 820, the locking belt 700 and the locking block 820 are rapidly pulled away under the elastic force of the first return spring 640 until the limiting plate 810 abuts against the bottom of the first support 560, so that the locking block 820 is also ensured to be in a vertical state, and the locking block 820 cannot interfere with the installation of the next ball milling tank.

Specifically, two receiving cavities are formed in the second support 570, the two receiving cavities are symmetrically arranged on two sides of the lock hole 571 in the length direction, each receiving cavity comprises a first cavity 572 and a second cavity 573 which are communicated, and the first cavity 572 is arranged between the lock hole 571 and the second cavity 573 and is communicated with the lock hole 571.

The locking mechanism 900 includes two sets of locking units 910 and a driving assembly 920, and the locking units 910 include a latch 911, a stopper 912, a sliding rod 913, and a second return spring 914. The clamping block 911 has an arc-shaped surface and a stopping surface, and the clamping block 911 is slidably fitted in the first cavity 572 and extends into the locking hole 571. The stopper 912 is disposed at a side of the second chamber 573 adjacent to the first chamber 572, and is coupled to the cartridge 911. The sliding rod 913 is arranged on one side of the stop block 912 departing from the clamping block 911, and the sliding rod 913 penetrates out of the second support 570. The second return spring 914 is disposed on the sliding rod 913, and two ends of the second return spring 914 are respectively connected to the stopper 912 and the inner sidewall of the second chamber 573. The locking block 820 is provided with two pushing portions 822, the pushing portions 822 are matched with the arc-shaped surfaces, and the driving assembly 920 is used for synchronously pulling the two sliding rods 913 to move away from each other, so that the two clamping blocks 911 are retracted into the first cavity 572.

After the locking block 820 is pulled to enable the locking belt 700 to bypass the limiting groove at the top of the ball milling pot and the locking block 820 is detached into the locking hole 571, the pushing portion 822 on the locking block 820 can push the arc-shaped surfaces of the fixture blocks 911, so that the two fixture blocks 911 are synchronously pushed into the corresponding first cavities 572, the fixture blocks 911 are tightly pushed against the side walls of the locking block 820, and in the process, the stop block 912 can compress the second return spring 914. When the locking groove 821 on the locking block 820 is aligned with the fixture block 911, the second return spring 914 rapidly pushes the fixture block 911 to be clamped into the locking groove 821, and the stop surface on the fixture block 911 ensures that the locking groove 821 cannot be separated from the limitation of the fixture block 911, so that the locking block 820 can be firmly locked on the second support 570.

Specifically, the drive assembly 920 includes a drive plate 921 and two pins 922. The drive plate 921 has two guide holes that are inverted-splayed, and the drive plate 921 deviates from the ball milling jar at the second support 570 along vertical sliding fit one side. The two pins 922 are respectively connected with the two sliding rods 913, the axes of the pins 922 are perpendicular to the axes of the sliding rods 913 on the horizontal plane, and each pin 922 penetrates through a corresponding guide hole. One side of the second support 570 departing from the ball milling tank is vertically provided with two third sliding grooves 574, the driving plate 921 is provided with two second sliding blocks, and the two second sliding blocks are respectively in sliding fit with the two third sliding grooves 574.

After the ball milling process is completed, when an operator presses the driving plate 921 downwards, the inner side wall of the inclined guide hole can support the pin 922, so that the pin 922 drives the sliding rod 913 to move towards a side far away from the second support 570, and thus the clamping block 911 is driven to return into the first cavity 572, and the locking belt 700 and the locking block 820 are pulled away quickly under the elastic force action of the first return spring 640, so that the unlocking operation of the locking block 820 is realized.

Specifically, in order to further improve the positioning and fixing effects on the ball milling tank, the tank fixing device further includes two positioning seats 580, the inner side wall of each positioning seat 580 is matched with the outer contour of the ball milling tank, a positioning groove 581 is formed in the inner side wall of each positioning seat 580, and a positioning block 140 matched with the positioning groove 581 is arranged on the outer side wall of the ball milling tank. Specifically, the positioning block 140 is disposed on the first tank 100.

In the description of the present invention, numerous specific details are set forth. It is understood, however, that embodiments of the invention may be practiced without these specific details. In some instances, well-known methods, structures and techniques have not been shown in detail in order not to obscure an understanding of this description.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; while the invention has been described in detail and with reference to the foregoing embodiments, it will be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention, and they should be construed as being included in the following claims and description.