CN211130766U

CN211130766U - Grind mechanism and grind machine

Info

Publication number: CN211130766U
Application number: CN201921839786.0U
Authority: CN
Inventors: 金文�; 胡伟
Original assignee: Individual
Current assignee: Individual
Priority date: 2019-10-29
Filing date: 2019-10-29
Publication date: 2020-07-31
Anticipated expiration: 2029-10-29

Abstract

The utility model discloses a grinding mechanism which can be used for grinding coffee beans and the like and comprises an upper grinding disc component and a lower grinding disc component which are arranged independently; the upper grinding disc component is provided with a connecting part which can be detachably connected with the outside, and the lower grinding disc component is driven by the outside to rotate and can be independently detached; the upper grinding disc assembly and the lower grinding disc assembly are matched with each other to form a grinding gap; the upper grinding disc assembly can move along the axial direction of the upper grinding disc assembly so as to adjust the size of the grinding gap; the lower grinding disc component is installed in place, and when the upper grinding disc component moves upwards along the axial direction to be in a limit tight fit state with the outside, the grinding gap is the maximum value. Correspondingly, the utility model also discloses a grind machine of having used aforementioned grinding mechanism. The utility model discloses not only can carry out the thickness of coffee powder steadily and adjust, can realize thorough, omnidirectional cleanness moreover, the structure is also comparatively simple.

Description

Grind mechanism and grind machine

Technical Field

The utility model belongs to the technical field of grind, concretely relates to grind mechanism and machine of grinding.

Background

With the gradual development of national economy, the requirements of people on the quality of life are higher and higher, and coffee as a daily drink has entered many common families. The quality of coffee is critical to the quality of coffee beans, but the taste of coffee depends on the freshness of the coffee powder. Even the coffee beans with good quality are ground into coffee powder and then placed for a certain time, the quality of the coffee beans is reduced to a certain extent. Based on this, more and more coffee loyalty enthusiasts prefer to have a coffee bean grinder for themselves, by grinding coffee beans to get fresher coffee powder. However, the conventional grinding machine has the following problems:

(1) for the traditional grinder, the lower grinding disc component which rotates dynamically is fixedly connected with the motor and is in a completely fixed state and cannot be detached, namely, a user can only detach the upper grinding disc component which is positioned at the upper part and is in a static state, so that the traditional grinder is quite troublesome in cleaning work and even cannot clean thoroughly, the taste of coffee liquid is influenced and great sanitation potential hazards are brought.

(2) The traditional grinder can only grind coffee powder with one fineness specification, can not adapt to the requirements of users with different tastes on different fineness at all, and has more assembly parts of a grinding mechanism, so that the assembly error can also influence the fineness and is not beneficial to ensuring the product quality.

(3) The structure of the traditional grinder is complex, the manufacturing process is complex, and the manufacturing cost is not reduced.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a remedy prior art not enough, provide a novel structure's grinding mechanism of coffee beans, it not only is favorable to carrying out the regulation of coffee powder thickness steadily, can realize thorough, omnidirectional cleanness moreover, and in addition, its structure is comparatively simple, is favorable to reducing manufacturing cost.

The utility model discloses a reach its purpose, the technical scheme of adoption as follows:

a grinding mechanism, its characterized in that:

the grinding device comprises an upper grinding disc assembly and a lower grinding disc assembly which are arranged independently;

the upper grinding disc assembly is provided with a connecting part which can be detachably connected with the outside, and the lower grinding disc assembly is driven by the outside to rotate and can be independently detached;

the upper grinding disc assembly and the lower grinding disc assembly are mutually matched to form a grinding gap; the upper grinding disc assembly can move along the axial direction of the upper grinding disc assembly so as to adjust the size of the grinding gap;

the lower grinding disc assembly is installed in place, and when the upper grinding disc assembly moves upwards along the axial direction of the upper grinding disc assembly to be in a limit tight fit state with the outside, the grinding gap is the maximum value.

Further, the connecting portion of the upper abrasive disc assembly is a first thread.

Further, the first thread is an external thread.

Correspondingly, the utility model also provides a grind the machine, have can adjust coffee powder thickness steadily, can thoroughly clean, advantages such as simple structure, it includes the host computer, its characterized in that:

the grinding machine also comprises a driving mechanism and the grinding mechanism;

the upper grinding disc assembly is detachably connected with the main machine through the connecting part on the upper grinding disc assembly, and the upper grinding disc assembly can move upwards along the axial direction of the upper grinding disc assembly to be in a limit tight fit state with the main machine;

the upper grinding disc assembly is connected with the main machine, so that when the grinding gap reaches a set requirement, the upper grinding disc assembly is limited and fixed to avoid rotation;

the lower grinding disc component can be detachably connected with the driving mechanism and rotates along with the driving mechanism;

the lower grinding disc assembly is connected in place, and when the upper grinding disc assembly and the main machine are in a limit tight fit state, the grinding gap is the maximum value.

Further, the drive mechanism is positioned above the upper grinding disc assembly; an output shaft of the driving mechanism axially penetrates through the upper grinding disc assembly and then is connected with the lower grinding disc assembly.

Furthermore, a feeding port is formed in the end face of the upper grinding disc assembly, and an output shaft of the driving mechanism axially penetrates through the feeding port and then is connected with the lower grinding disc assembly.

Further, go up the mill subassembly pass through connecting portion with the host computer is detachable connection, and its structural style includes:

the connecting part is a first thread, and a second thread is arranged on the host; the first and second threads are threaded such that the upper abrasive disc assembly is movable in an axial direction thereof.

Further, the first thread is an external thread located on the outer wall of the upper grinding disc assembly, and the second thread is an internal thread located on the inner side of the main machine.

Further, the upper grinding disc assembly is connected with the main machine, so that when the grinding gap reaches a set requirement, the upper grinding disc assembly is limited and fixed to avoid rotating, and one structural form of the upper grinding disc assembly comprises:

a plurality of telescopic first ejector rods are arranged on the upper grinding disc component, and a plurality of first concave parts are arranged on the main machine; the upper grinding disc assembly is connected with the main machine, so that when the grinding gap reaches a set requirement, the first ejector rods are respectively matched with the first concave parts to limit and fix the upper grinding disc assembly, and the upper grinding disc assembly is prevented from rotating.

Furthermore, each first ejector rod is provided with a spring assembly.

Further, the upper grinding disc assembly is connected with the main machine, so that when the grinding gap reaches a set requirement, the upper grinding disc assembly is limited and fixed to avoid rotation, and the other structural form of the upper grinding disc assembly comprises:

a plurality of telescopic second ejector rods are arranged on the main machine, and a plurality of second concave parts are arranged on the upper grinding disc component; the upper grinding disc assembly is connected with the main machine, so that when the grinding gap reaches a set requirement, the second ejector rods are respectively matched with the second concave parts, so that the upper grinding disc assembly is limited and fixed, and the upper grinding disc assembly is prevented from rotating.

Furthermore, each second ejector rod is provided with a spring assembly.

Further, the lower grinding disc assembly can rotate synchronously with the driving mechanism.

Furthermore, a flat part is arranged on an output shaft of the driving mechanism, and a first through hole is arranged on the end surface of the lower grinding disc component; the flat part is matched with the flat part of the first through hole, so that the lower grinding disc component and the driving mechanism rotate synchronously.

Furthermore, the grinding machine also comprises a lower grinding disc fixing nut;

a third thread is arranged on the output shaft of the driving mechanism and is positioned between the flat part and the head part of the output shaft of the driving mechanism; and after the flat part is matched with the flat part of the first through hole, the lower grinding disc fixing nut is in threaded fit with the third thread so as to fixedly connect the lower grinding disc assembly to the driving mechanism.

Furthermore, a cylinder convenient for operation and installation is arranged on the lower grinding disc component.

Furthermore, a guide block for guiding the raw material to be ground to flow into the grinding gap is arranged in the feeding port.

Furthermore, the outer wall of the upper grinding disc assembly is uniformly provided with limit scale marks, and the host is provided with mark lines which can correspond to the limit scale marks.

Furthermore, a power interface connected with an external power supply, a control circuit board and a start button are arranged on the host; the power interface and the starting key are electrically connected with the control circuit board.

Further, the driving mechanism is a grinding motor, and a first damping part is arranged between the driving mechanism and the host; the grinding machine is characterized in that a grinding amount adjusting knob is further arranged on the main machine, and the grinding amount adjusting knob and the grinding motor are electrically connected with the control circuit board.

Further, a storage bin for containing raw materials to be ground is arranged on the main machine; the grinding gap is in communication with the storage bin.

Furthermore, a baffle plate is arranged on the host; the baffle plate can rotate for a certain angle along the circumferential direction of the main machine so as to open or close a passage between the storage bin and the grinding gap;

the storage bin and the connection part of the passage between the grinding gaps and the host are provided with sealing strips.

Further, the storage bin is annularly arranged outside the grinding motor.

Further, a first cover body is arranged on the storage bin, and a second damping part is arranged between the first cover body and the storage bin; and a silica gel area is arranged on the end surface of the first cover body.

Further, the grinding machine also comprises a safety protection cover, and a discharge hole is formed in the safety protection cover;

the safety protection cover lock extremely during the host computer, the safety protection cover will go up the mill subassembly with the whole envelope of mill subassembly down, just grind the clearance with the discharge gate communicates each other.

Furthermore, the inner side of the safety protection cover is provided with a safety step surface for avoiding the mutual attachment of the upper grinding disc assembly and the lower grinding disc assembly.

Furthermore, a safety switch is arranged on the host and is electrically connected with the control circuit board; a first protruding part is arranged at the port of the safety shield;

when the safety protection cover is correctly buckled to the main machine, the first protruding part triggers the safety switch to start the grinder to work.

Further, safety protection casing lock to the host computer, its structural style includes:

the outer wall of the main machine is provided with a second protruding part, the inner wall of the safety protection cover is provided with a third sunken part, and the flow direction of the third sunken part faces to a port of the safety protection cover;

the second protrusion may be snap-fit with the third recess such that the safety shield is snapped onto the host.

Further, the grinder also comprises a cup body which is communicated with the discharge hole.

Further, the discharge gate is located safety protection cover's bottom, the cup is located safety protection cover under.

Further, a telescopic second cover body is arranged on the cup body; a second through hole communicated with the inside of the cup body is formed in the second cover body, and a sealing ring is arranged at the second through hole;

when the discharge port is communicated with the second through hole, the second cover body tightly pushes the discharge port, so that the interior of the cup body and the interior of the safety protection cover are sealed.

Further, a spring assembly is arranged on the second cover body; the inner side of the second cover body is provided with a fourth depressed part, the outer wall of the cup body is provided with a third protruding part, and the third protruding part is in snap fit with the fourth depressed part, so that the second cover body is arranged on the cup body.

Furthermore, a plug block used for plugging the second through hole is arranged on the second cover body.

Furthermore, a support is further arranged on the host, and a wiring groove used for limiting the swing of the connecting wire between the power interface and the external power supply is arranged on the support.

Furthermore, a base capable of placing the cup body is arranged on the support, and a bottom suction cup is arranged at the bottom of the base.

Correspondingly, the utility model also provides a grinding method, grinding operation is comparatively simple, convenient, and user experience feels stronger, a serial communication port, including following step:

preparing a raw material to be ground;

installing the aforementioned grinder: connecting the upper grinding disc assembly to the main machine and the lower grinding disc assembly to the driving mechanism;

the upper grinding disc assembly is moved along the axial direction of the upper grinding disc assembly so as to adjust the grinding gap and ensure the grinding thickness;

starting the driving mechanism to work so as to drive the lower grinding disc assembly to rotate;

and putting the raw material to be ground into the grinding gap to finish grinding.

Furthermore, after the grinding gap is adjusted, a safety protection cover is buckled on the main machine, so that the upper grinding disc assembly and the lower grinding disc assembly are integrally enveloped, and the discharge hole of the safety protection cover is communicated with the grinding gap.

Further, safety protection cover lock extremely back on the host computer, with a cup with safety protection cover the sealed intercommunication of discharge gate.

Compared with the prior art, the beneficial effects of the utility model are that:

(1) the utility model provides a grinding mechanism for grinding coffee beans, including the upper millstone subassembly and the lower millstone subassembly that set up independently each other, the two can be dismantled respectively, and experiments prove that the upper millstone subassembly and the lower millstone subassembly that remove can even be put into the dish washer and wash, thereby can realize thorough, comprehensive cleanness, and then not only be favorable to guaranteeing the taste of coffee liquid, but also guarantee the health of coffee liquid; in the grinding mechanism of the utility model, the upper grinding disc component can move along the axial direction thereof to adjust the size of the grinding gap, and the grinding mechanism is completely different from the structure of the traditional grinding mechanism in that, in the grinding mechanism of the utility model, when the lower grinding disc component is installed in place and the upper grinding disc component moves upwards along the axial direction thereof to be in a limit close fit state with the outside, the grinding gap is the maximum value, thereby not only realizing the adjustment of the thickness of the coffee powder, but also having extremely stable thickness adjustment, being beneficial to ensuring the product quality; furthermore, grinding mechanism structure comparatively simple, be favorable to reducing manufacturing cost.

(2) The utility model also provides a grinder, which comprises a host machine, a driving mechanism and the grinding mechanism, when the upper grinding disc component is connected with the host machine so that the grinding gap reaches the set requirement, the upper grinding disc component can be limited and fixed to avoid rotating, which is more favorable for ensuring the stability of the thickness adjustment; moreover, when the upper grinding disc assembly and the lower grinding disc assembly are both detached for cleaning, other areas inside the grinding machine of the utility model are more exposed, which is more beneficial to ensuring all-round and thorough cleaning; furthermore, the whole structure of the grinder is simple and light.

(3) The utility model correspondingly provides a grinding method of coffee beans, based on grind advantages such as simple structure, the operating procedure of this grinding method is very simple, convenient, user experience feels strong.

Drawings

The technology of the present invention will be further described in detail with reference to the accompanying drawings and detailed description:

fig. 1 is a schematic structural view of an upper disc assembly and a lower disc assembly according to embodiment 1 of the present invention;

fig. 2 is an exploded view of the assembly of the main machine of embodiment 2 and the grinding mechanism of embodiment 1 of the present invention;

fig. 3 is a schematic structural view of an upper millstone assembly, a lower millstone assembly and a lower millstone fixing nut according to embodiment 2 of the invention;

fig. 4 is an overall sectional view of a grinding machine of embodiment 2 of the present invention;

fig. 5 is a schematic structural view of a first cover body according to embodiment 2 of the present invention;

fig. 6 is a schematic structural view of a safety shield according to embodiment 2 of the present invention;

fig. 7 is a schematic view of an assembly structure of a cup body and a second cover body according to embodiment 2 of the present invention;

fig. 8 is another overall sectional view of the grinding machine of embodiment 2 of the present invention;

fig. 9 is an overall exploded view of the grinder of embodiment 2 of the present invention;

fig. 10 is an isometric view of a grinding mill of example 2 of the present invention;

fig. 11 is a schematic view of the inspection assembly using the minimum clearance standard template according to embodiment 2 of the present invention;

fig. 12 is an electric control schematic diagram of a grinder of embodiment 2 of the present invention;

fig. 13 is an overall sectional view of a grinding machine of embodiment 3 of the present invention;

fig. 14 is a partial sectional view of a grinder according to embodiment 3 of the present invention.

Reference numerals:

1-a grinding mechanism;

11-an upper grinding disc assembly; 111-external threads; 112-a feeding port; 1121-guide block; 113-a first ejector pin; 114-a second recess; 115-limit scale lines; 116-a cylinder; 1101-upper grinding cutter head; 1102-a cutterhead support;

12-a lower grinding disc assembly; 121 — a first via; 122-a cylinder; 1201-lower grinding cutter head; 1202-lower cutter head support;

2-a grinder;

21-a host; 211-internal thread; 212-a first recess; 213-second ejector pin; 214-mark line; 215-control circuit board; 216-start button; 217-grinding amount adjusting knob; 218-a safety switch; 219 — a second protrusion;

22-a drive mechanism; 221-flat portion; 222-third thread; 223-a first cushioning portion;

23-lower millstone fixing nut;

24-a storage bin; 241-a first cover; 2411-a silica gel area; 2412-self-sealing area; 242 — a second cushioning portion; 243-decorative cover plate; 244-a clamping ring;

25-a baffle plate;

26-a safety shield; 261-discharge hole; 262-safety step face; 263-first protrusion; 264-third recess;

27-a cup body; 271-a second cover; 2711 — a second via; 2712-a fourth recess; 272-a third protrusion; 273-chock; 274-a flexible connector; 27101-upper cover; 27102-middle cover; 27103-lower cover;

28-a scaffold; 281-a wiring groove;

29-a base; 291-footing suction cup;

3-minimum gap standard template.

Detailed Description

The conception, specific structure and technical effects of the present invention will be described clearly and completely with reference to the accompanying drawings and embodiments, so as to fully understand the objects, aspects and effects of the present invention. It should be noted that the embodiments and features of the embodiments in the present application may be combined with each other without conflict. The same reference numbers will be used throughout the drawings to refer to the same or like parts.

It should be noted that, unless otherwise specified, when a feature is referred to as being "fixed" or "connected" to another feature, it may be directly fixed or connected to the other feature or indirectly fixed or connected to the other feature. Furthermore, the description of the upper, lower, left, right, etc. used in the present invention is only relative to the mutual positional relationship of the components of the present invention in the drawings.

Example 1:

a grinding mechanism 1, as shown in FIG. 1, includes an upper grinding disc assembly 11 and a lower grinding disc assembly 12, which are independently disposed.

Wherein, the upper grinding disc assembly 11 is provided with a connecting part which can be detachably connected with the exterior, the exterior can be a specific bracket 28 or a shell, and other parts which can fix the upper grinding disc assembly 11.

The lower disc assembly 12 is independently removable and is externally driven, either manually or electrically, such as by hand or by a motor connection.

As can be appreciated from the above-described configuration, both upper grinding disk assembly 11 and lower grinding disk assembly 12 can be individually removed for thorough cleaning, thereby preventing coffee powder from being moldy and affecting the taste of the subsequent coffee liquid and the health of the user due to long-term accumulation of coffee powder on upper grinding disk assembly 11 and/or lower grinding disk assembly 12.

Wherein upper grinding disc assembly 11 and lower grinding disc assembly 12 cooperate to form a grinding gap; the upper grinding disc assembly 11 is movable in its axial direction to adjust the size of the grinding gap. Through the adjustment of the movement of the upper grinding disc assembly 11 along the axial direction thereof, the size of the grinding gap can be adjusted to grind coffee powder with different thicknesses, so that the requirements of different users on different thicknesses of the coffee powder are met.

The lower grinding disc assembly 12 is mounted in place and the upper grinding disc assembly 11 is moved axially upwardly to a limit interference fit with the exterior, the grinding gap being at a maximum. In other words, the upper disc assembly 11 is at its maximum clearance when uppermost, and as the upper disc assembly 11 moves downwardly, the grinding clearance becomes smaller, the further down the grinding clearance becomes smaller. This structural design has overturned the design theory of traditional grinding mechanism completely, and is extremely novel, unique, and for traditional grinding mechanism, the regulation of its coffee powder thickness degree is more stable, is favorable to guaranteeing product quality. In addition, the grinding mechanism is simple in structure and beneficial to reducing the manufacturing cost.

In this embodiment, the connecting portion of the upper grinding disc assembly 11 is a first thread, and can be fixedly connected with the outside through the first thread, and the upper grinding disc assembly 11 can be translated along the axial direction thereof through adjustment of the first thread, so as to achieve the effect of adjusting the size of the grinding gap, and the structure is extremely simple.

In this embodiment, the first thread is provided as an external thread 111, and the corresponding external portion connected thereto has an internal thread 211 engaged with the external thread 111. Of course, the first thread is not limited to an external thread, but rather it may also be provided as an internal thread, and the external part connected to it is then provided with an external thread that cooperates with the internal thread.

As shown in fig. 1, the upper grinding disc assembly 11 includes an upper grinding disc 1101 and an upper disc holder 1102, and a circular material inlet 112 is provided between the upper disc holder 1102 and the upper grinding disc 1101. The upper grinding cutter head 1101 is fixed on an upper cutter head bracket 1102 through screws and is coaxial with the upper cutter head bracket 1102, and the outer periphery of the upper cutter head bracket 1102 is provided with an external thread 111 matched with the internal thread 211 of the main machine 21. Of course, upper abrasive disc assembly 11 may also be integrally formed.

As shown in fig. 1, the lower grinding disc assembly 12 includes a lower grinding disc 1201 and a lower disc support 1202, the lower grinding disc 1201 is fixed to the lower disc support 1202 by screws, and the flat portion 221 is provided on the lower disc support 1202. Of course, lower abrasive disc assembly 12 may also be integrally formed.

Example 2:

the embodiment discloses a grinder 2, which has the advantages of being capable of stably adjusting the thickness of coffee powder, thoroughly cleaning, simple in structure and the like, and comprises a main machine 21, a driving mechanism 22 and the grinding mechanism 1 of the embodiment 1 as shown in fig. 1 to 12.

As shown in fig. 2, the upper grinding disc assembly 11 is detachably connected to the main machine 21 through a connecting portion thereon, and the upper grinding disc assembly 11 can move upward along the axial direction thereof to a limit tight-fitting state with the main machine 21. Lower abrasive disc assembly 12 may be removably coupled to drive mechanism 22 and rotate with drive mechanism 22. The lower grinding disc assembly 12 is connected in place, and when the upper grinding disc assembly 11 and the main machine 21 are in a limit tight-fit state, the grinding gap is the maximum value.

In order to make the ground coffee powder finer, the upper grinding disc assembly 11 is simply adjusted from top to bottom; to make the ground coffee powder coarser, the upper grinding disc assembly 11 needs to be adjusted from bottom to top. The thickness of the coffee powder can be adjusted by adjusting the upper grinding disc assembly 11 up and down.

Moreover, because the upper grinding disc assembly 11 is detachably connected with the main machine 21, and the lower grinding disc assembly 12 is detachably connected with the driving mechanism 22, when cleaning is needed, the upper grinding disc assembly 11 and the lower grinding disc assembly 12 can be respectively detached to clean, and meanwhile, other areas inside the grinder 2 can be exposed more, so that the grinder can be cleaned comprehensively and thoroughly, and further coffee powder can be prevented from being accumulated on the upper grinding disc assembly 11 and/or the lower grinding disc assembly 12 for a long time and being mildewed inside the grinder 2 to influence the taste of subsequent coffee liquid and the body health of a user.

It should be noted that drive mechanism 22 may be a manual rocker, which may be actuated by a user to rotate lower grinding disc assembly 12 for grinding; this actuating mechanism 22 also can be the motor, and the drive through the motor drives lower grinding disk subassembly 12 and carries out the rotary grinding, compares in the mode of carrying out the grinding through manual rocker, and it is more convenient to adopt the motor to carry out the mode of driving. Thus, in this embodiment, the drive mechanism 22 is a grinding motor. The connection of the grinding motor to lower grinding disc assembly 12 may be either a direct connection or a connection via another transmission mechanism, as long as lower grinding disc assembly 12 can be driven to rotate for grinding.

In addition, in order to ensure the stability of the coffee powder thickness adjustment and the grinding efficiency, the upper grinding disc assembly 11 is connected with the main machine 21 so that when the grinding gap reaches the set requirement, the upper grinding disc assembly 11 is limited and fixed to avoid rotation. If when the adjustment grinding clearance reaches the demand, the head stone subassembly 11 does not fix, then head stone subassembly 11 may be along with lower head stone subassembly 12 syntropy rotation together, though both can have certain speed difference, still can realize the grinding action, but the fineness degree of the coffee powder of ground gained can be unstable, influences the taste of coffee liquid to the efficiency of grinding is lower, thereby the time of extension grinding, and the utility model discloses a carry out spacing fixed with head stone subassembly 11, can avoid head stone subassembly 11 to take place rotatoryly when grinding, thereby guarantee the stability of coffee powder fineness degree regulation effectively, guarantee the efficiency of grinding. The specific structure for achieving this limited securement to prevent rotation of upper abrasive disc assembly 11 will be described in greater detail below.

In the present embodiment, as shown in fig. 2-4, drive mechanism 22 is located above upper abrasive disc assembly 11; the output shaft of the driving mechanism 22 axially penetrates through the upper grinding disc assembly 11 and then is connected with the lower grinding disc assembly 12, that is, the output shaft of the driving mechanism 22 penetrates through the upper grinding disc assembly 11 from top to bottom, and the lower grinding disc assembly 12 is detachably arranged on the output shaft. During disassembly, the lower grinding disc assembly 12 can be disassembled from the output shaft, and then the upper grinding disc assembly 11 can be disassembled from the main machine 21. In the conventional grinding machine, the driving mechanism is disposed below the grinding disc assemblies (including the upper and lower grinding disc assemblies), and due to the limitation of this structure, on one hand, assuming that the grinding thickness of the conventional grinding machine can be adjusted, the finest grinding gap (which is usually required by the industry to be 0.34mm) must be set first, but due to manufacturing errors and installation errors, the finest grinding gap of each grinding machine is wrong in mass production, so in order to achieve consistency, the finest grinding gap must be adjusted one by one in the manufacturing process, which results in a cumbersome manufacturing process and an increase in manufacturing cost, and further, the detachable connection structure of the lower grinding disc assembly 12 and the output shaft of the driving mechanism 22 is required to be very high, i.e. the thickness of the connection structure must be smaller than the finest grinding gap (for example, if a nut fixing manner is adopted, the thickness of the nut must be less than 0.34mm, which in turn imposes extremely high requirements on the strength of the nut); on the other hand, conventional grinders must be provided with a special passage to allow the ground coffee to escape from the underlying drive mechanism 22 and then enter the container, thus not only making the overall grinder bulky, but also making the overall cleaning of the device less advantageous. The grinder of the present embodiment breakthroughly places the driving mechanism 22 on the top, which effectively solves the aforementioned problems of the conventional grinder, i.e. not only effectively ensures the stability of the coffee powder fineness adjustment, but also makes the overall structure of the device simpler and lighter, has a wider range of selection of the manufacturing materials of the device, and is convenient for the thorough cleaning of the device.

As shown in fig. 2, a material inlet 112 is disposed on an end surface of the upper grinding disc assembly 11, and an output shaft of the driving mechanism 22 axially penetrates through the material inlet 112 and then is connected to the lower grinding disc assembly 12. The inlet 112 is an inlet for coffee beans, and during the grinding process, the coffee beans fall into the grinding gap between the upper grinding disc assembly 11 and the lower grinding disc assembly 12 through the inlet 112 for grinding. The output shaft passes through the feeding port 112 to be connected with the lower grinding disc assembly 12, so that the lower grinding disc assembly 12 is ensured to rotate, meanwhile, the output shaft does not interfere with the upper grinding disc assembly 11, the driving mechanism 22 and the like, and the normal operation of grinding action is ensured.

In this embodiment, as in embodiment 1, the upper grinding disc assembly 11 is detachably connected to the main frame 21 through the connecting portion, and its structure form includes:

the connecting part is a first thread, and a second thread is arranged on the main machine 21; the first thread is screwed with the second thread so that the upper grinding disc assembly 11 can move along the axial direction thereof, i.e. the two are screwed to realize the adjustment of the grinding gap.

In the present embodiment, as shown in fig. 1 and 2, the first thread is provided as an external thread 111 located on the outer wall of the upper grinding disc assembly 11, and the second thread is provided as an internal thread 211 located inside the main machine 21. Of course, adjustment of the grinding gap can also be achieved by a structural adjustment in which the first thread is an internal thread on the inner wall of the upper grinding disc assembly 11 and the second thread is an external thread on the outside of the main frame 21.

In this embodiment, the upper grinding disc assembly 11 is connected to the main machine 21 so that when the grinding gap reaches a set requirement, the upper grinding disc assembly 11 is fixed in a limited manner to avoid rotation, and the structural form thereof includes:

as shown in fig. 4, the main body 21 is provided with a plurality of retractable second push rods 213; as shown in fig. 1 and 4, the upper grinding disc assembly 11 is provided with a plurality of second recesses 114; when the upper grinding disc assembly 11 is connected with the main machine 21 so that the grinding gap reaches a set requirement, each second ejector rod 213 and each second concave part 114 are respectively matched to enable the upper grinding disc assembly 11 to be limited and fixed, and the upper grinding disc assembly 11 is prevented from rotating.

Based on this structural design, after adjusting the upper millstone component 11 to the position, the second ejector rod 213 stretches out and enters the second depressed part 114, so that the upper millstone component 11 can be limited and fixed on the main machine 21, the upper millstone component 11 is prevented from rotating during grinding, the instability of the fineness of the coffee powder is avoided, and the grinding efficiency is favorably ensured.

The end of the second top rod 213 is a smooth end, the second recess 114 is a smooth groove, and can just accommodate and only accommodate the smooth end, when the position of the upper grinding disc assembly 11 needs to be adjusted, a torsion is applied to the upper grinding disc assembly 11, the smooth end slips off from the second recess 114 and the second top rod 213 shortens at the same time, so that the second top rod 213 can be separated from the second recess 114, the upper grinding disc assembly 11 can rotate relative to the main machine 21, the axial position of the upper grinding disc assembly 11 can be adjusted, and the size of the grinding gap can be adjusted. In the process of adjusting the upper grinding disc assembly 11, when the second ejector rod 213 rotates to just correspond to the second recess 114, the second ejector rod 213 extends again and is matched with the second recess 114, when the torsion is applied again, the second ejector rod 213 can be separated from the second recess 114, and in such a cycle, the position of the upper grinding disc assembly 11 can be adjusted in the axial direction.

Specifically, each of the second push rods 213 is provided with a spring assembly. As shown in fig. 4, the second push rod 213 is provided with a flange engaged with the spring assembly, one end of the spring assembly abuts against the flange, the other end abuts against the hole of the host 21, the spring assembly is compressed when the second push rod 213 retracts, and the spring assembly ejects the second push rod 213 when the second push rod 213 extends. More specifically, the spring assembly is a compression spring.

In this embodiment, lower abrasive disc assembly 12 may rotate synchronously with drive mechanism 22. In order to prevent the output shaft of the lower grinding disc assembly 12 and the output shaft of the driving mechanism 22 from rotating relatively during grinding, the present embodiment is designed as follows: a flat part 221 is arranged on the output shaft of the driving mechanism 22, and a first through hole 121 is arranged on the end surface of the lower grinding disc assembly 12; flat portion 221 mates with first throughbore 121 in a flat position to allow lower abrasive disc assembly 12 to rotate in unison with drive mechanism 22. The flat portion 221 and the first through hole 121 cannot rotate relatively after being matched with each other in a flat manner, but can slide relatively in the axial direction, so that the lower grinding disk assembly 12 can be detached by sliding towards the head of the output shaft of the driving mechanism 22 on the premise of ensuring the synchronous rotation effect.

Based on the above structure, in order to avoid the lower grinding disc assembly 12 sliding up and down on the output shaft of the driving mechanism 22 during grinding, thereby affecting the grinding gap and the grinding effect, the following design is made in the present embodiment:

as shown in fig. 2 to 4, the grinder 2 further includes a lower disc fixing nut 23; a third thread 222 is arranged on the output shaft of the driving mechanism 22 and is positioned between the flat part 221 and the head part of the output shaft of the driving mechanism 22; when the flat portion 221 is in flat engagement with the first through hole 121, the lower disc fixing nut 23 is in threaded engagement with the third thread 222, so as to fixedly connect the lower disc assembly 12 to the driving mechanism 22. The lower grinding disc fixing nut 23 is in threaded fixed fit with the third thread 222 on the output shaft of the driving mechanism 22, so that the lower grinding disc assembly 12 can be axially fixed on the output shaft of the driving mechanism 22, the lower grinding disc assembly 12 cannot axially slide in a fixed state, and the grinding gap and the grinding effect are ensured.

From here, the circumferential movement of lower grinding disc assembly 12 on the output shaft of actuating mechanism 22 is restricted by flat position 221 and the flat position cooperation of first through-hole 121, the axial movement of lower grinding disc assembly 12 on the output shaft of actuating mechanism 22 is restricted by lower grinding disc fixation nut 23 and third screw 222 screw-thread fit, realized dismantling fixedly to lower grinding disc assembly 12 and actuating mechanism 22's output shaft, only need unscrew lower grinding disc fixation nut 23 when needs dismantle, can be with lower grinding disc assembly 12 and actuating mechanism 22's output shaft separation.

In order to facilitate the rotational removal of lower disc retaining nut 23, in the present embodiment, as shown in fig. 1, lower disc assembly 12 is provided with a cylinder 122 for easy mounting. In the non-energized state, the output shaft of the driving mechanism 22 is rotatable, so that the user can pinch or block the cylinder 122 to unscrew or screw the lower grinding disc fixing nut 23, thereby facilitating the disassembly of the lower grinding disc fixing nut 23 and the disassembly and assembly of the lower grinding disc assembly 12.

In the present embodiment, as shown in fig. 1, a guide block 1121 is disposed inside the feeding port 112, and the guide block 1121 is used for orderly guiding the raw material to be ground (such as coffee beans, etc.) entering from the feeding port 112 to flow into the grinding gap for grinding, so as to prevent the raw material to be ground from falling into the grinding gap all at once and affecting the grinding effect.

In this embodiment, in order to facilitate the user to quickly and precisely adjust the grinding gap, as shown in fig. 1 and 2, the outer wall of the upper grinding disc assembly 11 is uniformly provided with limit graduation lines 115, the main machine 21 is provided with marking lines 214 corresponding to the limit graduation lines 115, and the user can adjust the required grinding gap according to the limit graduation lines 115 and the marking lines 214 to grind coffee powder with required thickness.

The marking lines 214 and the limit scale lines 115 are marked when the factory leaves, and the specific marking method is as follows:

1. firstly, assembling the upper grinding disc assembly 11 and the main machine 21 and adjusting the upper grinding disc assembly 11 to the highest position;

2. sleeving the minimum clearance standard template 3 for production on an output shaft of the driving mechanism 22, as shown in fig. 11;

3. the lower grinding disc assembly 12 and the output shaft of the driving mechanism 22 are assembled and fixed, then the gap between the upper grinding disc assembly 11 and the lower grinding disc assembly 12 is the maximum gap at the moment, and the position is marked;

4. lowering the upper grinding disc assembly 11 to fully compress the minimum gap standard template 3, and marking the position when the gap between the upper grinding disc assembly 11 and the lower grinding disc assembly 12 is the minimum gap;

5. and silk-printing each limit scale line 115 and the mark line 214 according to the marked position.

By this method, the error of the grinding gap generated in the manufacturing process of each grinding machine can be corrected quickly and effectively. The driving mechanism of the conventional grinding machine is disposed below the grinding assembly, and when the upper and lower grinding disc assemblies are tightened, the gap between the two is the minimum gap, which takes much time if the error of the grinding gap generated in the manufacturing process needs to be corrected. In other words, in the present embodiment, the grinding gap between the upper and lower grinding disc assemblies can be adjusted and calibrated and marked quickly based on the upper position of the driving mechanism 22, so that the workload of the production and manufacture of the grinding machine is greatly reduced, which is beneficial to reducing the production cost.

In this embodiment, as shown in fig. 9, the host 21 is provided with a power interface for connecting an external power supply, a control circuit board 215, and a start button 216; the power interface and the start button 216 are electrically connected to a control circuit board 215, and the electrical control schematic diagram is shown in fig. 12. After the external power source is connected through the power interface, the user presses the start button 216, and the control circuit board 215 starts the driving mechanism 22 to grind according to a preset program, so that the operation of the user is reduced in an electric control mode.

As shown in fig. 4, the driving mechanism 22 is a grinding motor, a first damping portion 223 is disposed between the grinding motor and the main machine 21, and the first damping portion 223 is an elastic cushion block, which may be a rubber block or a silica gel block, and is used for reducing vibration caused by the working of the grinding motor and reducing working noise; as shown in fig. 12, the main body 21 is further provided with a grinding amount adjusting knob 217, and the grinding amount adjusting knob 217 and the grinding motor are electrically connected to the control circuit board 215. The grinding amount adjusting knob 217 can adjust the operating time of the grinding motor electrically connected to the control circuit board 215, thereby adjusting the grinding amount.

As shown in fig. 9 to 11, the main body 21 is provided with a storage bin 24 for containing the raw material to be ground; the grinding gap is communicated with the storage bin 24, specifically, the grinding gap is communicated with the storage bin 24 through the feeding port 112, so that, for example, after a user puts coffee beans to be ground into the storage bin 24, the coffee beans can enter the grinding gap from the feeding port 112 to be ground for grinding, and actions of putting the coffee beans by the user are reduced.

As shown in fig. 9, in order to control the amount of the raw material to be ground to be fed, a stopper 25 is provided on the main machine 21; the baffle 25 can rotate a certain angle along the circumferential direction of the main machine 21 to open or close the passage between the storage bin 24 and the grinding gap; specifically, the flap 25 is hinged to the main body and is located to one side of the passageway. When the separation blade 25 is opened, the raw material to be ground in the storage bin 24 continuously falls into the grinding gap for grinding, and when the separation blade 25 is slowly closed, the amount of the raw material to be ground in the storage bin 24 falling into the grinding gap is gradually reduced, namely, the opening and closing of the channel is controlled by the separation blade 25, so that the control of the inflow of the raw material to be ground is realized.

The connection between the passage between the storage bin 24 and said grinding gap and the main body 21 is provided with a sealing strip, which prevents the coffee powder produced during the grinding process from drifting out of the passage and into other parts of the main body 21, thus risking contamination of the subsequent coffee powder.

The storage chamber 24 may be disposed inside the main body 21 or outside the main body 21, and in this embodiment, the storage chamber 24 is disposed inside a housing of the main body 21, as shown in fig. 4 and 8, specifically, the storage chamber 24 is disposed around the outside of the grinding motor.

In this embodiment, as shown in fig. 4 and 5, the storage bin 24 is provided with a first cover 241 for sealing the storage bin 24, and a second damping portion 242 is provided between the storage bin 24 and the first cover 241, so as to achieve the effects of damping and reducing noise; the second shock absorption part 242 is an elastic cushion block, which may be a rubber cushion block or a silica gel cushion block; be equipped with silica gel district 2411 on the terminal surface of first lid 241, silica gel district 2411 has the self-sealing area 2412 that can supply the finger to insert together, because silica gel district 2411 has elasticity, when the finger inserts from the self-sealing area 2412, from the sunken deformation of sealing area 2412 for the finger can be scratched and is sealed area 2412, thereby can extract whole first lid 241 in order to separate with storage storehouse 24, and then can put into the coffee beans. When the finger leaves the self-sealing area 2412, the self-sealing area 2412 rebounds to restore its original shape, i.e., the self-sealing area 2412 is in a planar state, so as to prevent foreign matters such as dust from being deposited on the self-sealing area 2412.

The silicone area 2411 and the first cover 241 are fixed by a pressing ring 244, the pressing ring 244 and the first cover 241 are fixed by a plurality of screws, the first cover 241 is further provided with a decorative cover plate 243, and the decorative cover plate 243 shields the screws.

As shown in fig. 4 and 6, the grinder 2 further includes a safety protection cover 26, and a discharge hole 261 is formed on the safety protection cover 26; when the safety protection cover 26 is buckled to the main machine 21, the safety protection cover 26 envelops the upper grinding disc assembly 11 and the lower grinding disc assembly 12 integrally so as to prevent the damage caused by touching the lower grinding disc assembly 12 rotating at a high speed in the grinding process, the grinding gap is communicated with the discharge hole 261, the ground coffee powder can be discharged from the discharge hole 261, and the ground coffee powder is prevented from scattering everywhere under the action of rotation inertia.

When the mounting position of upper grinding disc assembly 11 is too low, upper grinding disc assembly 11 and lower grinding disc assembly 12 may contact each other, and in such a case, grinding may cause the two grinding disc assemblies to collide with each other, thereby causing damage. To solve this problem, in this embodiment, the safety shield 26 is provided with a safety step surface 262 on the inner side thereof to prevent the upper grinding disc assembly 11 and the lower grinding disc assembly 12 from being attached to each other. As shown in fig. 4 and 6, a section of cylinder 116 extends downwards from the upper grinding disc assembly 11, when the height of the upper grinding disc assembly 11 is the lowest value of the safety height, the lowest end of the cylinder 116 is just in contact with the safety step surface 262, and the safety shield 26 can be normally installed on the main machine 21, but when the upper grinding disc assembly 11 is installed at a lower position, the lowest end of the cylinder 116 will abut against the safety step surface 262, so that the safety shield 26 cannot be normally installed on the main machine 21, so that when a user finds that the safety shield 26 is not installed, the installation height of the upper grinding disc assembly 11 is too low, and the upper grinding disc assembly 11 can be timely adjusted to the normal height, thereby effectively avoiding the upper grinding disc assembly 11 and the lower grinding disc assembly 12 from colliding with each other, and then the safety shield 26 is installed, and grinding is started.

In order to ensure that the safety shield 26 is installed in place during each grinding operation to avoid the damage to the user caused by starting grinding without installing the safety shield 26, as shown in fig. 8, a safety switch 218 is arranged on the main machine 21 and electrically connected with the control circuit board 215; a first protrusion 263 is provided at a port of the safety shield 26; when the safety shield 26 is properly fastened to the main body 21, the first protrusion 263 activates the safety switch 218 to start the operation of the grinder 2. If the user does not install the safety protection cover 26, the safety switch 218 is not triggered by the first protrusion 263, and the grinding machine 2 cannot be started, thereby avoiding the potential safety hazard caused by starting the grinding operation without installing the safety protection cover 26.

In this embodiment, as shown in fig. 4 and 6, the safety shield 26 is fastened to the main frame 21, and its structure form includes:

the outer wall of the main unit 21 is provided with a second protrusion 219, the inner wall of the safety shield 26 is provided with a third recess 264, and the flow direction of the third recess 264 is a port facing the safety shield 26; the second protrusion 219 may snap-fit with the third recess 264 such that the safety shield 26 is snapped onto the host 21. The installation and removal of the safety shield 26 may be facilitated by the engagement of the second protrusion 219 with the third recess 264.

In this embodiment, as shown in fig. 4 and 7, grinder 2 further includes a cup 27 in communication with outlet 261, cup 27 for receiving coffee grounds discharged from outlet 261.

More specifically, the discharge hole 261 is located at the bottom of the safety shield 26, so that the coffee powder coming out of the grinding gap can be discharged from the discharge hole 261 under the action of gravity after falling into the safety shield 26; the cup 27 is positioned directly below the safety shield 26 so that ground coffee discharged from the discharge port 261 continues to fall into the cup 27 under the force of gravity.

Due to the rotational inertia of the lower grinding disk assembly 12, the ground coffee powder has a certain speed, and if the coffee powder is directly discharged from the discharge port 261 into the cup 27, the coffee powder may be scattered from the discharge port 261 and may not fall into the cup 27 completely, i.e., a part of the coffee powder may be scattered into the surrounding air, which causes waste and air pollution.

In order to solve the above problem, in the present embodiment, as shown in fig. 4 and 7, a retractable second cover 271 is provided on the cup 27; a second through hole 2711 communicated with the inside of the cup body 27 is formed in the second cover body 271, and a sealing ring is arranged at the second through hole 2711 to ensure the sealing connection with the discharge hole 261; when the discharge port 261 is communicated with the second through hole 2711, the second cover 271 tightly pushes the discharge port 261, so that the inside of the cup 27 and the inside of the safety shield 26 are both sealed.

Based on the structure, the second cover body 271 on the cup body 27 is directly connected with the discharge hole 261 in a sealing manner, so that the discharged coffee powder is completely guided into the cup body 27, and the occurrence of powder flying is avoided; and the telescopic second cover 271 can be butted with the discharge ports 261 with different heights, that is, the cup 27 can be adapted to the discharge ports 261 of the grinding machines 2 with different heights.

Specifically, a spring assembly is disposed on the second cover 271, as shown in fig. 7, the second cover 271 is divided into an upper cover 27101, a middle cover 27102 and a lower cover 27103, the spring assembly is a compression spring, the middle cover 27102 is provided with a hole for mounting the compression spring, the upper cover 27101 passes through the middle cover 27102 and is fixed with the lower cover 27103, the compression spring is located between the upper cover 27101 and the middle cover 27102, the middle cover 27102 is connected and fixed with the cup body 27, and the distance between the upper cover 27101 and the middle cover 27102 can be extended and retracted by the compression spring to adapt to the discharge ports 261 with different heights. The inner side of the second cover 271 is provided with a fourth recess 2712, specifically, the inner side of the middle cover 27102 is provided with a fourth recess 2712, the outer wall of the cup 27 is provided with a third protrusion 272, and the third protrusion 272 and the fourth recess 2712 are in snap fit, so that the second cover 271 is disposed on the cup 27. The third protrusion 272 and the fourth recess 2712 can detachably connect the second cover 271 with the cup 27, so that the second cover 271 can be conveniently taken down after receiving coffee powder, and the coffee powder in the cup 27 can be poured out.

When the coffee powder is not contained, external dust or other foreign matters may enter the cup body 27 through the second through hole 2711, and affect subsequent use, as shown in fig. 7, a plug 273 for plugging the second through hole 2711 is provided on the second cover body 271, and when the cup body 27 is not used, the plug 273 can be used for plugging the second through hole 2711, so as to prevent the external dust or other foreign matters from entering the cup body 27. The stopper 273 may be independently provided, or may be connected to the second cover 271 or the cup 27 via the flexible connector 274. The flexible linkage 274 may be a plastic strap, or string, etc.

In this embodiment, as shown in fig. 10, the main body 21 is further provided with a bracket 28, and the bracket 28 is provided with a wire slot 281 for limiting the swing of the connection wire between the power interface and the external power source, so that the appearance of the grinding machine 2 is cleaner and tidier, and the abrasion of the connection wire by a foreign object during daily use can be avoided.

In this embodiment, as shown in fig. 11, a base 29 on which the cup 27 can be placed is provided on the stand 28, a foot suction cup 291 is provided on the bottom of the base 29, and the foot suction cup 291 is provided to fix the base 29 to a table or other supporting body on which the present grinder 2 is placed by suction, so as to prevent shaking and noise generation due to excessive vibration during grinding.

Example 3:

the present embodiment discloses another grinding mill 2, which is different from the grinding mill 2 of embodiment 2 in that:

in this embodiment, the upper grinding disc assembly 11 is provided with a plurality of retractable first push rods 113, and the main frame 21 is provided with a plurality of first concave portions 212; when the upper grinding disc assembly 11 is connected with the main machine 21 so that the grinding gap reaches a set requirement, each first ejector rod 113 and each first concave part 212 are respectively matched to enable the upper grinding disc assembly 11 to be limited and fixed, and the upper grinding disc assembly 11 is prevented from rotating. As shown in fig. 13 and 14, the upper grinding disc assembly 11 is provided with a blind hole for the first top bar 113 to be mounted and extended. After the position of the upper grinding disc assembly 11 is adjusted, the first ejector rod 113 extends into the first concave part 212, so that the upper grinding disc assembly 11 is fixed on the main machine 21 in a limiting manner, the upper grinding disc assembly 11 is prevented from rotating during grinding, and the instability of grinding thickness and the reduction of grinding efficiency are avoided.

Similar to the structure of embodiment 2, the end of the first top rod 113 is a smooth end, the first recess 212 is a smooth groove, and can just accommodate and only accommodate the smooth end, when adjusting the position of the upper grinding disc assembly 11, a torsion is applied to the upper grinding disc assembly 11, the smooth end slips off from the first recess 212 and the first top rod 113 shortens at the same time, so that the first top rod 113 is separated from the first recess 212, and the upper grinding disc assembly 11 can rotate relative to the main machine 21, so that the position of the upper grinding disc assembly 11 can be adjusted in the axial direction, and the size of the grinding gap can be adjusted. In the process of adjusting the upper grinding disc assembly 11, when the first push rod 113 rotates to correspond to the first recess 212 exactly, the first push rod 113 extends again to be matched with the first recess 212, if a torque force is applied again, the first push rod 113 can be separated from the first recess 212, and the position of the upper grinding disc assembly 11 in the axial direction can be adjusted in such a circulating manner.

Specifically, each first top bar 113 is provided with a spring assembly, and the spring assembly is a specific structure for realizing the telescopic function of the first top bar 113. As shown in fig. 14, the first top rod 113 is provided with a flange matching with the spring assembly, one end of the spring assembly abuts against the flange, the other end abuts against the blind hole of the upper grinding disc assembly 11, the spring assembly is compressed when the first top rod 113 retracts, and the first top rod 113 is ejected by the spring assembly when the first top rod 113 extends. Wherein the spring assembly is a compression spring.

Example 4:

the embodiment provides a grinding method, the grinding operation is simple and convenient, the user experience is strong, and the method comprises the following steps:

1. preparing a raw material to be ground; inserting fingers into a self-sealing area 2412 of a silica gel area 2411 of the first cover body 241, separating the first cover body 241 from the storage bin 24, adding raw materials to be ground into the storage bin 24, and then covering the first cover body 241;

2. installation of the grinder 2 of example 2 or 3: connecting the upper grinding disc assembly 11 to the main machine 21, ensuring that the upper grinding disc assembly 11 is mounted at the highest point, and connecting the lower grinding disc assembly 12 to the driving mechanism 22;

3. moving the upper grinding disc assembly 11 along the axial direction of the upper grinding disc assembly 11 by referring to the limit scale lines 115 and the mark lines 214 so as to adjust the grinding gap and ensure the grinding thickness;

4. after the grinding gap is adjusted, a safety protection cover 26 is buckled on the main machine 21 so as to integrally envelop the upper grinding disc assembly 11 and the lower grinding disc assembly 12, and a discharge hole 261 of the safety protection cover 26 is communicated with the grinding gap;

5. after the safety protection cover 26 is fastened to the main machine 21, the fastening is ensured to be in place, namely the safety switch 218 is in a triggered state, and then the cup body 27 is in sealed communication with the discharge hole 261 of the safety protection cover 26 to prepare for containing ground coffee powder;

6. starting a grinding amount adjusting button, selecting a required grinding amount, then pressing a starting button 216, and starting a driving mechanism 22 (which can be a grinding motor) to work so as to drive the lower grinding disc assembly 12 to rotate;

7. the baffle plate 25 is opened, the raw material to be ground is put into the grinding gap to start grinding, and the ground coffee powder falls into the cup body 27; after the raw material to be ground in the grinding gap is ground, the start button 216 is pressed again, the driving mechanism 22 is closed, grinding is completed, the cup body 27 is taken down, coffee powder in the cup body is poured out, and coffee can be brewed.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the present invention in any way, so that any modification, equivalent change and modification made by the technical spirit of the present invention to the above embodiments do not depart from the technical solution of the present invention, and still fall within the scope of the technical solution of the present invention.

Claims

1. A grinding mechanism, its characterized in that:

2. The grinding mechanism of claim 1, wherein: the connecting portion of the upper abrasive disc assembly is a first thread.

3. The grinding mechanism of claim 2, wherein: the first thread is an external thread.

4. A grinding machine comprising a main machine, characterized in that:

further comprising a drive mechanism, a grinding mechanism as claimed in any one of claims 1 to 3;

5. A grinding mill according to claim 4, characterized in that: the drive mechanism is positioned above the upper grinding disc assembly; an output shaft of the driving mechanism axially penetrates through the upper grinding disc assembly and then is connected with the lower grinding disc assembly.

6. A grinding mill according to claim 5, characterized in that: the end face of the upper grinding disc assembly is provided with a feeding port, and an output shaft of the driving mechanism axially penetrates through the feeding port and then is connected with the lower grinding disc assembly.

7. A grinding mill according to any one of claims 4 to 6, wherein the upper grinding disc assembly is detachably connected to the main machine through the connecting part, and the structure form of the grinding mill comprises:

8. A grinding mill according to claim 7, characterized in that: the first thread is an external thread located on the outer wall of the upper grinding disc assembly, and the second thread is an internal thread located on the inner side of the main machine.

9. A grinding machine according to any one of claims 4 to 6 wherein the upper grinding disc assembly is connected to the main machine such that when the grinding gap is set, the upper grinding disc assembly is held against rotation by a limited amount, and one form of construction comprises:

10. A grinding mill according to claim 9, characterized in that: each first ejector rod is provided with a spring assembly.

11. A grinding machine according to any one of claims 4 to 6 wherein the upper grinding disc assembly is connected to the main machine such that when the grinding gap reaches a set requirement, the upper grinding disc assembly is restrained from rotating, and another form of construction comprises:

12. A grinding mill according to claim 11, characterized in that: and each second ejector rod is provided with a spring assembly.

13. A grinding mill according to any one of claims 4 to 6, characterized in that: the lower grinding disc assembly can rotate synchronously with the driving mechanism.

14. A grinding mill according to claim 13, characterized in that: the output shaft of the driving mechanism is provided with a flat part, and the end surface of the lower grinding disc component is provided with a first through hole; the flat part is matched with the flat part of the first through hole, so that the lower grinding disc component and the driving mechanism rotate synchronously.

15. A grinding mill according to claim 14, characterized in that:

the grinding machine also comprises a lower grinding disc fixing nut;

16. A grinding mill according to claim 15, characterized in that: and a cylinder convenient for operation and installation is arranged on the lower grinding disc component.

17. A grinding mill according to claim 6, characterized in that: and a guide block for guiding the raw material to be ground to flow into the grinding gap is arranged in the feeding port.

18. A grinding mill according to any one of claims 4 to 6, characterized in that: the outer wall of the upper grinding disc assembly is uniformly provided with limit scale marks, and the host is provided with mark lines which can correspond to the limit scale marks.

19. A grinding mill according to any one of claims 4 to 6, characterized in that: the host is provided with a power interface connected with an external power supply, a control circuit board and a start key; the power interface and the starting key are electrically connected with the control circuit board.

20. A grinding mill according to claim 19, wherein: the driving mechanism is a grinding motor, and a first damping part is arranged between the driving mechanism and the host; the grinding machine is characterized in that a grinding amount adjusting knob is further arranged on the main machine, and the grinding amount adjusting knob and the grinding motor are electrically connected with the control circuit board.

21. A grinding mill according to claim 20, wherein: the main machine is provided with a storage bin for containing raw materials to be ground; the grinding gap is in communication with the storage bin.

22. A grinding mill according to claim 21, characterized in that:

a baffle plate is arranged on the host; the baffle plate can rotate for a certain angle along the circumferential direction of the main machine so as to open or close a passage between the storage bin and the grinding gap;

23. A grinding mill according to claim 21, characterized in that: the storage bin is annularly arranged outside the grinding motor.

24. A grinding mill according to claim 21, characterized in that: the storage bin is provided with a first cover body, and a second damping part is arranged between the first cover body and the second cover body; and a silica gel area is arranged on the end surface of the first cover body.

25. A grinding mill according to claim 19, wherein:

the grinding machine also comprises a safety protection cover, and a discharge hole is formed in the safety protection cover;

26. A grinding mill according to claim 25, wherein: the inner side of the safety protection cover is provided with a safety step surface for preventing the upper grinding disc assembly and the lower grinding disc assembly from being attached to each other.

27. A grinding mill according to claim 25, wherein:

the host is provided with a safety switch which is electrically connected with the control circuit board; a first protruding part is arranged at the port of the safety shield;

28. A grinding mill according to claim 25 wherein the safety shield is snap fitted to the main machine in a form which includes:

29. A grinding mill according to claim 25, wherein: the grinder also comprises a cup body which is communicated with the discharge hole.

30. A grinding mill according to claim 29, wherein: the discharge gate is located safety protection cover's bottom, the cup is located safety protection cover is under.

31. A grinding mill according to claim 29, wherein:

a telescopic second cover body is arranged on the cup body; a second through hole communicated with the inside of the cup body is formed in the second cover body, and a sealing ring is arranged at the second through hole;

32. A grinding mill according to claim 31, wherein: a spring assembly is arranged on the second cover body; the inner side of the second cover body is provided with a fourth depressed part, the outer wall of the cup body is provided with a third protruding part, and the third protruding part is in snap fit with the fourth depressed part, so that the second cover body is arranged on the cup body.

33. A grinding mill according to claim 31, wherein: and the second cover body is provided with a plug block for plugging the second through hole.

34. A grinding mill according to claim 29, wherein: the host is also provided with a support, and the support is provided with a wiring groove for limiting the swing of the connecting wire between the power interface and the external power supply.

35. A grinding mill according to claim 34, wherein: the cup body is arranged on the support, the bottom of the base is provided with a bottom sucker, and the cup body is placed on the bottom of the support.