CN108721108B - Moxa cone processing device and method - Google Patents

Abstract

The invention relates to a moxa cone processing device and a moxa cone processing method, comprising the following steps: the device comprises a pressurizing column, a pressure bearing column, a first driving mechanism, a second driving mechanism, a table plate, a first heating piece, a second heating piece and a third heating piece. When the moxa cone processing device is used, moxa to be processed is filled in the processing through hole; then, the first actuating mechanism drives the pressurization post and gets into the processing through-hole from one of them one end of processing through-hole, and the pressure-bearing post is fixed on the second actuating mechanism, and one of them one end of pressure-bearing post stretches into the processing through-hole for the moxa can be detained in the processing through-hole inside. Moxa is in the inside pressure that is exerted of processing through-hole pressurized column, simultaneously, at the in-process that moxa shaping becomes the moxa column, the both ends and the middle part of moxa column heat through first heating piece, second heating piece and third heating piece. At this time, moxa sticks to each other under the condition of heating and pressurizing, so that the density of the moxa cone is effectively improved, and the forming effect of the moxa cone is ensured.

Description

Moxa cone processing device and method

Technical Field

The invention relates to the technical field of medical care, in particular to a moxa cone processing device and a moxa cone processing method.

Background

Moxa-moxibustion often carries out physiotherapy to the human body through the moxa cone, and the moxa cone forms through stock form and moxa roll-up, then burns the moxa cone, and the volatile flue gas of moxa has certain treatment to the human body. The forming mode of the moxa cone mainly comprises the step of wrapping and forming the moxa by the roll paper, but the roll paper is limited by tension of the roll paper, and the density of the formed moxa cone is not high, so that the moxa cone cannot be fully combusted, and the forming effect of the moxa cone is poor.

Disclosure of Invention

Accordingly, it is necessary to provide a moxa cone processing apparatus and method capable of improving the molding effect of moxa cones.

The technical scheme is as follows:

a moxa cone processing device, comprising:

the device comprises a pressurizing column, a pressure bearing column, a first driving mechanism, a second driving mechanism and a table plate, wherein the first driving mechanism is connected with the pressurizing column, the second driving mechanism is connected with the pressure bearing column, the table plate is arranged between the pressurizing column and the pressure bearing column, a processing through hole is formed in the table plate, the pressurizing column and the pressure bearing column are arranged corresponding to the processing through hole, and the pressurizing column and the pressure bearing column can extend into the processing through hole; the heating device comprises a first heating piece, a second heating piece and a third heating piece, wherein the first heating piece is connected with a pressurizing column, the second heating piece is connected with the second heating column, the third heating piece is arranged inside a table plate, and the third heating piece is used for improving the temperature inside a processing through hole.

When the moxa cone processing device is used, moxa to be processed is filled in the processing through hole; then, the first actuating mechanism drives the pressurization post and gets into the processing through-hole from one of them one end of processing through-hole, and the pressure-bearing post is fixed on the second actuating mechanism, and one of them one end of pressure-bearing post stretches into the processing through-hole for the moxa can be detained in the processing through-hole inside. Moxa is in the inside pressure that is exerted of processing through-hole pressurized column, simultaneously, at the in-process that moxa shaping becomes the moxa column, the both ends and the middle part of moxa column heat through first heating piece, second heating piece and third heating piece. At this time, moxa sticks to each other under the condition of heating and pressurizing, so that the density of the moxa cone is effectively improved, and the forming effect of the moxa cone is ensured.

The technical scheme is further described as follows:

the desk plate further comprises a machining plate, a plurality of machining through holes are formed in the machining plate, a mounting opening is formed in the desk plate, and the machining plate stretches into the mounting opening to be connected with the desk plate.

The processing board includes first processing board and second processing board, processing through-hole includes first processing through-hole and second processing through-hole, follows the lateral wall of installing port has seted up many draw-in grooves, first processing board with all seted up on the second processing board be used for with draw-in groove matched with buckle, just first processing board with second processing board superpose cooperation, a plurality of have been seted up on the first processing board first processing through-hole, a plurality of have been seted up on the second processing board second processing through-hole, works as first processing board with the second processing board simultaneously with when the table links to each other, first processing board with the second processing board is contradicted each other, just first processing through-hole with the second processing through-hole corresponds the intercommunication.

The moxa cone processing device further comprises a first connecting plate and a second connecting plate, wherein the first connecting plate is connected with the first driving mechanism, the second connecting plate is connected with the second driving mechanism, the pressurizing columns comprise a plurality of first pressurizing sub-columns, the pressure-bearing columns comprise a plurality of first pressure-bearing sub-columns, the first pressurizing sub-columns are arranged on the first connecting plate, and the first pressure-bearing sub-columns are arranged on the second connecting plate.

One end of the pressure-bearing column extends into the processing through hole, the other end of the pressure-bearing column is in interference fit with the second connecting plate, and the maximum distance between the second connecting plate and the table plate is smaller than the length of the pressure-bearing column.

The moxa cone processing device further comprises a baffle plate and a plurality of guide columns, wherein the guide columns are connected with the table plate, a plurality of through holes corresponding to the guide columns are formed in the table plate, one ends of the guide columns are movably connected with the first connecting plate, the other ends of the guide columns penetrate through the through holes and are movably connected with the second connecting plate, and the baffle plate is erected between the second connecting plate and the second driving mechanism through the guide columns.

The moxa cone processing device further comprises a heating mechanism, a first heating piece, a second heating piece and a third heating piece are all connected with the heating mechanism, the first heating piece is arranged on the first connecting plate, the first pressurizing sub-columns are connected with the first connecting plate through the first heating piece, the second heating piece is arranged on the second connecting plate, the first pressurizing sub-columns are connected with the second connecting plate through the second heating piece, the third heating piece is arranged inside the table plate, and the third heating piece is sleeved outside the processing through hole.

The moxa cone processing device further comprises a pushing plate and a telescopic rod, wherein the telescopic rod is arranged on the table plate, the pushing plate is connected with the telescopic rod, and the telescopic rod can drive the pushing plate to horizontally move along the surface of the processing plate.

A moxa cone processing method comprises the following steps: filling moxa to be processed into the processing through hole; heating and pressurizing moxa in the processing through hole simultaneously; and ejecting the processed moxa from the processing through hole.

When the moxa is processed in the processing through hole, the pressure born by the processing through hole is 6 pa-8 pa, the temperature of the pressurizing column is 120-130 ℃, the temperature of the side wall of the processing through hole is 120-130 ℃, and the temperature of the pressure bearing column is 140-150 ℃.

The moxa cone processing method is used for processing moxa by heating and pressurizing. Specifically, moxa exhibits a certain viscosity during this heating process, and then, the moxa is bonded under pressure. Thereby make moxa need not the stock form parcel and can take shape into the moxa cone, and the density of moxa cone can change through regulation and control heating temperature and pressurization pressure to the combustion effect of moxa cone has been improved greatly. More specifically, the moxa cone manufactured by the moxa cone manufacturing method does not have any additional material (such as roll paper), so that no pollution gas or harmful gas is generated in the gas generated by the combustion of the moxa cone, and the using effect of the moxa cone is improved.

Drawings

Fig. 1 is a schematic structural diagram of an moxa cone processing device according to an embodiment;

FIG. 2 is an enlarged view of a portion A of FIG. 1;

fig. 3 is a flowchart of a moxa cone processing method according to an embodiment.

Reference numerals illustrate:

100. the device comprises a pressurizing column, 110, a first heating element, 120, a first connecting plate, 130, a first pressurizing sub-column, 200, a pressure-bearing column, 210, a second heating element, 220, a second connecting plate, 230, a first pressure-bearing sub-column, 300, a first driving mechanism, 400, a second driving mechanism, 500 table boards, 510, processing through holes, 520, processing boards, 530, mounting ports, 540, baffle boards, 550, guide columns, 560, pushing boards, 570 and a third heating element.

Detailed Description

The present invention will be further described in detail with reference to the drawings and the detailed description, in order to make the objects, technical solutions and advantages of the present invention more apparent. It should be understood that the detailed description and specific examples are intended for purposes of illustration only and are not intended to limit the scope of the invention.

It will be understood that when an element is referred to as being "fixed to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like are used herein for illustrative purposes only and are not meant to be the only embodiment.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.

The terms "first" and "second" in this specification do not denote a particular quantity or order, but rather are used for distinguishing between similar or identical items.

As shown in fig. 1 and 2, in one embodiment, a moxa cone processing device includes: the pressing column 100, the pressing column 200, the first driving mechanism 300, the second driving mechanism 400, the table 500, the first heating member 110, the second heating member 210, and the third heating member 570 (not shown). The first driving mechanism 300 is connected to the pressing column 100, and the second driving mechanism 400 is connected to the pressure receiving column 200. The table 500 is disposed between the pressing column 100 and the pressure-bearing column 200, a processing through hole 510 is formed in the table 500, the pressing column 100 and the pressure-bearing column 200 are disposed corresponding to the processing through hole 510, and the pressing column 100 and the pressure-bearing column 200 can extend into the processing through hole 510. The first heating element 110 is connected to the pressing column 100, the second heating element 210 is connected to the second heating column, the third heating element 570 is mounted inside the table 500, and the third heating element 570 is used for increasing the temperature inside the processing through hole 510.

The first driving mechanism 300 and the second driving mechanism 400 are oil cylinders or oil cylinders. Considering that the moxa cone is in the shaping time, if the too big pressure in moxa cone middle part can lead to the moxa cone to appear the fault phenomenon, influence the result of use of moxa cone. Therefore, the middle part of moxa cone is heated through third heating element 570, has improved the viscidity of moxa this moment, has also improved the tolerance at moxa cone middle part simultaneously for the moxa cone shaping back is compacter, and the shaping effect of moxa cone is better. Further, since moxa is processed inside the processing through hole 510, the optimal molding time of the moxa is limited. Therefore, the first driving mechanism 300 and the second driving mechanism 400 are both cylinders. This embodiment of the present embodiment can enable the pressing column 100 to be lowered by a preset pressure value under the driving of the first driving mechanism 300, that is, the required processing pressure value of the moxa is already reached when the pressing column 100 and the moxa in the processing through hole 510 touch each other, thereby greatly improving the forming effect of the moxa.

Specifically, in this embodiment, an oil pump is further disposed outside the moxa cone processing device. The first driving mechanism 300 and the second driving mechanism 400 are both connected to an oil pump. Two oil pressure branch pipes are led out from the oil outlet end of the oil pump, wherein one oil pressure branch pipe is a pressurizing branch pipe, and the other oil pressure branch pipe is a pressure-bearing branch pipe. The pressurizing branch pipe is connected with the first driving mechanism 300, the pressure-bearing branch pipe is connected with the second driving mechanism 400, and control valves, for example, are respectively arranged on the pressurizing branch pipe and the pressure-bearing branch pipe: when the first driving mechanism 300 applies pressure to the pressurizing column 100, the control valve on the pressurizing branch pipe is opened, and the control valve on the pressurizing branch pipe is closed. Further, after the pressurizing column 100 pressurizes the moxa in the processing through hole 510, the first driving mechanism 300 drives the pressurizing column 100 to draw out from the processing through hole 510. At this time, the control valve on the pressurizing branch pipe is closed, the control valve on the pressurizing branch pipe is opened, the second driving mechanism 400 drives the pressure-bearing column 200 to move inside the processing through hole 510, and the processed moxa cone can extend out from one end of the processing through hole 510 under the driving of the pressure-bearing column 200. Therefore, the oil pump can independently control the pressurizing column 100 and the pressure bearing column 200, thereby improving the utilization rate of the driving mechanism and reducing the processing cost of the moxa cone. Such an implementation as described above is just one example, for example: under the condition that the oil pump meets the normal pressure value required by oil cylinder processing, a plurality of oil pressure branch pipes can be arranged at the oil outlet end of the oil cylinder, and each oil pressure branch pipe is correspondingly connected with the corresponding oil cylinder.

When the moxa cone processing device is used, moxa to be processed is firstly filled in the processing through hole 510; then, the first driving mechanism 300 drives the pressurizing column 100 to enter the processing through hole 510 from one end of the processing through hole 510, the pressure bearing column 200 is fixed on the second driving mechanism 400, and one end of the pressure bearing column 200 extends into the processing through hole 510, so that moxa can be retained inside the processing through hole 510. The moxa is pressurized by the pressurizing column 100 inside the processing through hole 510, and simultaneously, both ends and the middle of the moxa are heated by the first heating element 110, the second heating element 210 and the third heating element 570 in the process of forming the moxa into the moxa. At this time, moxa sticks to each other under the condition of heating and pressurizing, so that the density of the moxa cone is effectively improved, and the forming effect of the moxa cone is ensured.

As shown in FIG. 1, in one embodiment, the table 500 also includes a tooling plate 520. The processing plate 520 is provided with a plurality of processing through holes 510, and the table 500 is provided with mounting openings 530 corresponding to the processing plate 520. Specifically, the processing plate 520 deforms when heated and pressurized. The mounting openings 530 are provided for receiving the tooling plate 520 to connect with the table 500, which is a design that facilitates later maintenance and replacement of the tooling plate 520.

In one embodiment, the tooling plate 520 includes a first tooling plate (not shown) and a second tooling plate (not shown). The processing through hole 510 includes a first processing through hole (not marked) and a second processing through hole (not marked), a plurality of clamping grooves are formed along the side wall of the mounting opening 530, and the first processing plate and the second processing plate are provided with buckles for matching with the clamping grooves. And the first processing plate is matched with the second processing plate in a superposition way, a plurality of first processing through holes are formed in the first processing plate, and a plurality of second processing through holes are formed in the second processing plate. When the first processing plate and the second processing plate are simultaneously connected with the table 500, the first processing plate and the second processing plate are mutually abutted, and the first processing through hole is correspondingly communicated with the second processing through hole.

Moxa cone processing device is when carrying out mass production to the moxa cone, sometimes needs to process the moxa cone of equidimension. Therefore, the first processing plate is provided with a first processing through hole corresponding to the pressing column 100 and the pressure receiving column 200, and the second processing plate is provided with a second processing through hole corresponding to the pressing column 100 and the pressure receiving column 200. Then, the first processing board or the second processing board with the holes is arranged on the table board 500, and at the moment, the buckles on the first processing board or the second processing board are matched with the clamping grooves on the table board 500. Because moxa cone processingequipment can cause certain influence to first processing board or second processing board in the course of working, consequently be equipped with connecting piece and a plurality of screw hole at the surface of table 500, just the screw hole is located the outer fringe of installing port. The connecting piece is a bolt or a screw, and the connecting piece passes through the threaded hole and is mutually abutted against the first processing plate or the second processing plate, so that the auxiliary fixing of the first processing plate or the second processing plate is realized.

In another embodiment, the table 500 is provided with a plurality of slots, so that the first processing board and the second processing board can be mounted on the table 500 at the same time. Specifically, when the first processing plate and the second processing plate are both mounted on the table 500, a sealing gasket is further disposed between the first processing plate and the second processing plate. The sealing gasket is provided with openings which are matched with the first processing through holes and the second processing through holes, so that the tightness of the first processing plate and the second processing plate is ensured, and the first processing through holes and the second through holes are corresponding and mutually communicated. This embodiment can effectively change the molding length of the moxa cone.

In one embodiment, the moxa cone processing device further comprises a first connecting plate 120 and a second connecting plate 220. The first connection plate 120 is connected to the first driving mechanism 300, and the second connection plate 220 is connected to the second driving mechanism 400. The pressing column 100 includes a plurality of first pressing sub-columns 130, the pressure-bearing column 200 includes a plurality of first pressing sub-columns 230, the first pressing sub-columns 130 are mounted on the first connection plate 120, and the first pressing sub-columns 230 are mounted on the second connection plate 220. The table 500 is provided with a plurality of processing through holes 510 corresponding to the pressing columns 100 and the pressure-bearing columns 200. The first connecting plate 120 and the second connecting plate 220 are located at two sides of the table 500, and the first connecting plate 120 and the second connecting plate 220 are connected to the guide posts 550.

Specifically, in consideration of the maximum pressure that can be output by the cylinder and the optimal pressurizing time for molding the moxa cone, 80 first pressurizing sub-columns 130 are provided on the first connecting plate 120, 80 second pressurizing sub-columns are provided on the second connecting plate 220, the pressurizing columns 100 are mounted on the first connecting plate 120 in a manner of 10×8 rows×columns, and the pressure receiving columns 200 are mounted on the second connecting plate 220 in a manner of 10×8 rows×columns. Meanwhile, 80 processing through holes 510 corresponding to the pressing columns 100 and the pressure receiving columns 200 are also formed in the table 500. The design method ensures that the distances between two adjacent pressurizing columns 100 are equal in the moxa cone forming process, so that the stress of the pressurizing columns 100 is more uniform, and the pressurizing effect of the pressurizing columns 100 on moxa is improved. Meanwhile, the processing efficiency of the moxa cone processing device on moxa is improved. This is just one implementation of the present example, for example: when the number of the first pressurizing sub-columns 130 is one or two, the oil cylinder can be adjusted to a smaller output pressure to perform the molding treatment on the moxa. The embodiment is mainly used for popularization and processing demonstration of moxa cone products.

In another embodiment, one end of the pressure-bearing post 200 extends into the through-hole 510, and the other end of the pressure-bearing post 200 is in interference fit with the second connecting plate 220. And the maximum distance between the second connecting plate 220 and the table 500 is smaller than the length of the compression column 200. So that moxa put into the inside of the processing through-hole 510 can be retained in the processing through-hole 510. Then, the first driving mechanism 300 delivers pressure to the pressing column 100 to drive the pressing column 100 into the processing through hole 510, and at this time, the pressure receiving column 200 is not ejected by the pressing column 100 under the auxiliary support of the second driving mechanism 400 and the second connection plate 220. Thus, inside the processing through hole 510, the pressing column 100 and the bearing column 200 achieve the relative pressing of moxa. Specifically, in the process of moxa cone molding, the second driving mechanism 400 drives the pressure bearing columns 200 to change the extending length of the pressure bearing columns 200 in the processing through holes 510, so that the moxa cone processing device can process moxa cones with different lengths.

Specifically, the pressurizing column 100 is adopted to enter from one end of the processing through hole 510 in the forming process and performs single-side extrusion on the moxa, and the extrusion mode can reduce the stress in the middle of the moxa to a certain extent, so that the success rate of the moxa in the processing through hole 510 in converting to the moxa is improved. Further, this single-sided compression concentrates the forces on the moxa and the compression column 200. Since the force between the pressure-receiving pillar 200 and the moxa is greater than the force between the pressure-receiving pillar 100 and the moxa. Accordingly, the compression column 200 requires higher heat than the compression column 100 to shape moxa near the compression column 200. In the process, the temperature of the pressurizing column 100 is 80-120 ℃, and the temperature of the pressure-bearing column 200 is 140-150 ℃. The pressurizing time for the pressurizing column 100 to extend into the processing through hole 510 is 2.5 min-3.5 min.

In one embodiment, the moxa cone processing device further comprises a baffle 540 and a plurality of guide posts 550. The guide post 550 is connected to the table 500, and the table 500 is provided with a plurality of through holes corresponding to the guide post 550, one end of the guide post 550 is movably connected to the first connecting plate 120, and the other end of the guide post 550 passes through the through holes to be movably connected to the second connecting plate 220. The barrier 540 is mounted between the second connection plate 220 and the second drive mechanism 400 via the guide posts 550. The pressurizing column 100 and the pressure receiving column 200 can be more accurately aligned with the end of the processing through hole 510 under the guidance of the guide column 550, so that the pressurizing column 100 and the pressure receiving column 200 are prevented from being deviated in the moving process.

The second driving mechanism 400 is connected to the second connection plate 220 according to the entire length of the compression column 200 and ensures that the interval between the second connection plate 220 and the table 500 is smaller than the entire length of the compression column 200. Specifically, since the compression column 200 is compressed and heated during the processing, the loss of the compression column 200 is large, so that the compression column 200 is detachably connected with the second connecting plate 220, thereby facilitating the replacement of the compression column 200. More specifically, a bump is further disposed on the guide post 550, and the bump is located between the second connecting plate 220 and the baffle plate 550, where when the second connecting plate 220, the baffle plate 550 and the bump are in contact with each other, the interval between the second connecting plate 220 and the table 500 is equal to the overall length of the pressure-bearing post 200. At this time, the second connecting plate 220 will not fall toward the baffle plate 550 under the limit of the bump, so as to avoid the falling of the pressure-bearing column 200 caused by the excessive interval between the second connecting plate 220 and the table 500. Specifically, according to the installation situation of the first processing board and the second processing board on the table board 500, at this time, the interval distance between the table board 500 and the second connecting board 220 may be changed, so that the whole length of the pressure-bearing column 200 may be fully utilized, and the baffle 540 may be lifted and adjusted along the guide column 550, so as to ensure that the length of the pressure-bearing column 200 may be fully utilized under different working conditions.

In one embodiment, the moxa cone processing device further comprises a heating mechanism (not shown). The first heating element 110, the second heating element 210 and the third heating element 570 are all connected to the heating mechanism. The first heating member 110 is disposed on the first connection plate 120, and the first pressing sub-column 130 is connected to the first connection plate 120 through the first heating member 110. The second heating element 210 is disposed on the second connecting plate 220, and the first pressure-bearing sub-column 230 is connected to the second connecting plate 220 through the second heating element 210. The third heating member 570 is disposed inside the table 500, and the third heating member 570 is sleeved outside the processing through hole 510. The first heating element 110, the second heating element 210 and the third heating element 570 are heating blocks or heating rings. The heating mechanism comprises a temperature controller and a temperature display, wherein the temperature controller is connected with the heating piece, and the temperature controller is electrically connected with the temperature display. The temperature display is also connected to the table 500, and the temperature of the surface of the table 500 is increased along with the heating of the heating element because the moxa needs a higher temperature during the processing. Therefore, in order to prevent the processed moxa stick from being removed from the table 500 or accidental burn when filling the processed through hole 510 in the table 500 with moxa, the temperature displayed on the temperature display may be observed in advance, and the moxa stick may be detached when the temperature is appropriate or the heat-insulating prop may be selected to detach the moxa stick. Further, the method comprises the steps of,

in one implementation, the first heating element 110 is a plurality of first heating elements 110 corresponding to the first pressing sub-column 130, the second heating element 210 is a plurality of second heating elements 210 corresponding to the one pressing sub-column, and the third heating element 570 is a plurality of third heating elements 570 corresponding to the processing through-hole 510. Specifically, the third heating elements 570 are in one-to-one correspondence with the processing through holes 510, so that the temperature inside the processing through holes 510 can reach the preheating temperature rapidly, and the molding effect of the moxa cone is improved.

In one embodiment, the moxa cone processing device further comprises a pusher plate 560 and a telescoping rod (not shown). The telescopic rod is arranged on the table plate 500, the pushing plate 560 is connected with the telescopic rod, and the telescopic rod can drive the pushing plate 560 to horizontally move along the surface of the processing plate 520. Specifically, after the moxa in the through-hole 510 is formed into the moxa stick, the pressing post 200 ejects the moxa stick from the inside of the through-hole 510. At this time, the telescopic rod drives the pushing plate 560 to move, and the pushing plate 560 can push the moxa cone ejected by the bearing column 200 out of the table 500 for recycling, so that the recycling efficiency of the moxa cone is improved.

As shown in fig. 3, in one embodiment, a moxa cone processing method includes the following steps: filling moxa to be processed into the processing through holes 510; the moxa in the processing through hole 510 is heated and pressurized at the same time; the finished moxa is ejected from the inside of the processing through hole 510. When the moxa is processed in the processing through hole 510, the pressure applied to the processing through hole 510 is 6pa to 8pa, the temperature of the pressurizing column 100 is 120 ℃ to 130 ℃, the temperature of the side wall of the processing through hole 510 is 120 ℃ to 130 ℃, and the temperature of the pressure-bearing column 200 is 140 ℃ to 150 ℃. Specifically, the aperture of the processed through hole 510 is 1.6cm, and the height of the hole is 2.2cm. First, the heating mechanism is turned on to preheat the processing through hole 510, the pressing column 100 and the pressure receiving column 200 on the table 500. Then weigh 240 g's moxa and place on table 500 and fill it in 80 processing through-holes 510, because the moxa is comparatively loose before the processing be difficult for filling in processing through-hole 510, so in order to guarantee that the moxa of every processing through-hole 510 inside is abundant, first actuating mechanism 300 can drive the compression column 100 and carry out a pre-compaction to the moxa, just can fill the moxa that remains on the table 500 to processing through-hole 510 inside after the pre-compaction is accomplished, guaranteed that the moxa of processing through-hole 510 inside is abundant. Finally, pressurizing and heating for 2.5-3 min to obtain the moxa cone with the surface diameter of 1.6 cm.

The moxa cone processing method is used for processing moxa by heating and pressurizing. Specifically, moxa exhibits a certain viscosity during this heating process, and then, the moxa is bonded under pressure. Thereby make moxa need not the stock form parcel and can take shape into the moxa cone, and the density of moxa cone can change through regulation and control heating temperature and pressurization pressure to the combustion effect of moxa cone has been improved greatly. More specifically, the moxa cone manufactured by the moxa cone manufacturing method does not have any additional material (such as roll paper), so that no pollution gas or harmful gas is generated in the gas generated by the combustion of the moxa cone, and the using effect of the moxa cone is improved.

The technical features of the above-described embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above-described embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.

The above examples illustrate only a few embodiments of the invention, which are described in detail and are not to be construed as limiting the scope of the invention. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of protection of the present invention is to be determined by the appended claims.

Claims (10)

1. A moxa cone processing device, comprising:

the device comprises a pressurizing column, a pressure bearing column, a first driving mechanism, a second driving mechanism and a table plate, wherein the first driving mechanism is connected with the pressurizing column, the second driving mechanism is connected with the pressure bearing column, the table plate is arranged between the pressurizing column and the pressure bearing column, a processing through hole is formed in the table plate, the pressurizing column and the pressure bearing column are respectively arranged corresponding to the processing through hole, the pressurizing column and the pressure bearing column can extend into the processing through hole, and when the first driving mechanism drives the pressurizing column to enter the processing through hole, the pressure bearing column can be kept in the processing through hole;

the first heating piece, second heating piece and third heating piece, first heating piece with the pressurization post links to each other, the second heating piece with the pressure-bearing post links to each other, the third heating piece is installed inside the table, just the third heating piece cover is established the outside of processing through-hole, the third heating piece is used for improving the inside temperature of processing through-hole, when moxa is in when processing through-hole is inside, the temperature of pressure-bearing post is 80 ~ 130 ℃, the temperature of processing through-hole lateral wall is 80 ~ 120 ℃, the temperature of pressure-bearing post is 140 ~ 150 ℃.

2. The moxa cone processing device according to claim 1, wherein the table further comprises a processing plate, a plurality of processing through holes are formed in the processing plate, a mounting opening is formed in the table, and the processing plate extends into the mounting opening to be connected with the table.

3. The moxa cone processing device according to claim 2, wherein the processing board includes first processing board and second processing board, processing through-hole includes first processing through-hole and second processing through-hole, follows the lateral wall of installing port has seted up many draw-in grooves, first processing board with all seted up on the second processing board be used for with draw-in groove matched with buckle, just first processing board with second processing board superposes the cooperation, a plurality of first processing through-hole has been seted up on the first processing board, a plurality of second processing through-hole has been seted up on the second processing board, when first processing board with the second processing board simultaneously with the table links to each other, first processing board with second processing board is contradicted each other, just first processing through-hole with second processing through-hole corresponds the intercommunication.

4. The moxa cone processing device according to claim 2, further comprising a first connecting plate and a second connecting plate, wherein the first connecting plate is connected to the first driving mechanism, the second connecting plate is connected to the second driving mechanism, the pressurizing column comprises a plurality of first pressurizing sub-columns, the pressure-bearing column comprises a plurality of first pressure-bearing sub-columns, the first pressurizing sub-columns are mounted on the first connecting plate, and the first pressure-bearing sub-columns are mounted on the second connecting plate.

5. The moxa cone processing device according to claim 4, wherein one end of the pressure-bearing column extends into the processing through hole, the other end of the pressure-bearing column is in interference fit with the second connecting plate, and a maximum distance between the second connecting plate and the table plate is smaller than a length of the pressure-bearing column.

6. The moxa cone processing device according to claim 4, further comprising a baffle plate and a plurality of guide posts, wherein the guide posts are connected with the table plate, a plurality of through holes corresponding to the guide posts are formed in the table plate, one end of each guide post is movably connected with the first connecting plate, the other end of each guide post penetrates through each through hole to be movably connected with the second connecting plate, and the baffle plate is erected between the second connecting plate and the second driving mechanism through the guide posts.

7. The moxa cone processing device according to claim 4, further comprising a heating mechanism, wherein the first heating element, the second heating element and the third heating element are all connected with the heating mechanism, the first heating element is arranged on the first connecting plate, the first pressurizing sub-column is connected with the first connecting plate through the first heating element, the second heating element is arranged on the second connecting plate, the first pressure-bearing sub-column is connected with the second connecting plate through the second heating element, the third heating element is arranged inside the table plate, and the third heating element is sleeved outside the processing through hole.

8. The moxa cone processing device according to any one of claims 1 to 7, further comprising a pushing plate and a telescopic rod, wherein the telescopic rod is arranged on the table, the pushing plate is connected with the telescopic rod, and the telescopic rod can drive the pushing plate to horizontally move along the surface of the processing plate.

9. A method of using the moxa cone processing device of claim 8, comprising the steps of:

filling moxa to be processed into the processing through hole;

heating and pressurizing moxa in the processing through hole simultaneously;

and ejecting the processed moxa from the processing through hole.

10. The method of claim 9, wherein when said moxa is processed in said processing hole, the pressure applied to the inside of said processing hole is 6pa to 8pa, the temperature of said pressing column is 80 ℃ to 130 ℃, the temperature of the side wall of said processing hole is 80 ℃ to 120 ℃, and the temperature of said pressure receiving column is 140 ℃ to 150 ℃.