CN219294837U - Moxa cone former - Google Patents

Abstract

The utility model discloses a moxa cone former, which comprises: a base; the moxa cone mold is arranged on the base and comprises a mold body and a plurality of ejection inserts, wherein a plurality of first cavities which are opened upwards are formed in the top of the mold body, through holes are formed in the mold body and are communicated with the first cavities and the bottom of the mold body, the ejection inserts are arranged in the through holes, the ejection inserts are accommodated in the through holes and are ejected upwards, a second cavity is formed in the top of the ejection inserts, and the first cavity and the second cavity are matched to form a third cavity; and the pressing plate is covered with the top of the die body. The utility model can facilitate the demoulding of the molded moxa cone, is convenient for operators to take out the moxa cone after demoulding, and ensures the integrality of the moxa cone.

Description

Moxa cone former

Technical Field

The utility model relates to the technical field of medical appliances, in particular to a moxa cone former.

Background

Moxa cone moxibustion is a treatment method which uses moxa to make small conical moxa cone by hands or by means of appliances, and the moxa cone is ignited and put on an acupoint to perform moxibustion, and the purposes of preventing and treating diseases and health care are achieved through the thermal and/or medicinal effects of burning.

The existing moxa cone manufacturing tool generally comprises a moxa cone mold and a pressing plate, wherein the moxa cone mold is provided with a plurality of inverted cone mold cavities, moxa raw materials are placed into the inverted cone mold cavities, the pressing plate and the mold are pressed, and moxa is compacted in the inverted cone mold cavities, so that conical moxa cones are obtained.

However, when the moxa cone mold is released, the moxa cone mold is usually required to be taken down, then the moxa cone mold is inverted and is flapped, so that the molded moxa cone is separated from the mold under the action of external force and self gravity, the moxa cone directly falls off after being released, the moxa cone is easy to damage, and the moxa cone is easy to adhere to the surface of the mold cavity after being compacted under the stress, so that the moxa cone is easy to scatter on the outer wall or difficult to release after being molded.

Disclosure of Invention

The present utility model aims to solve at least one of the technical problems existing in the prior art. Therefore, the moxa cone forming device provided by the utility model can be used for conveniently demoulding the formed moxa cone, so that an operator can conveniently take out the demoulded moxa cone, and the integrality of the moxa cone is ensured.

According to an embodiment of the utility model, a moxa cone former comprises: a base; the moxa cone mold is arranged on the base and comprises a mold body and a plurality of ejection inserts, wherein a plurality of first cavities which are opened upwards are formed in the top of the mold body, through holes are formed in the mold body and are communicated with the first cavities and the bottom of the mold body, the ejection inserts are arranged in the through holes, the ejection inserts are accommodated in the through holes and are ejected upwards, a second cavity is formed in the top of the ejection inserts, and the first cavity and the second cavity are matched to form a third cavity; and the pressing plate is covered with the top of the die body.

The moxa cone former according to the embodiment of the utility model has at least the following beneficial effects:

1. according to the moxa cone manufacturing method, the base, the moxa cone mould and the pressing plate are arranged, the base can support the moxa cone mould, a proper amount of moxa is placed into the plurality of third cavities in the moxa cone mould, then the pressing plate and the moxa cone mould are covered, the moxa in the third cavities is pressed by the pressing plate, the pressure is maintained for a certain time, and then the plurality of molded moxa cones are obtained by opening the pressing plate, so that a plurality of moxa cones with uniform specifications can be manufactured at the same time, and the production efficiency of the moxa cones is improved.

2. According to the utility model, the mold body and the plurality of ejection inserts are arranged, the mold body is provided with the plurality of first cavities and the plurality of through holes, the ejection inserts are provided with the second cavities, before mold closing, the plurality of ejection inserts are respectively put into the plurality of through holes from top to bottom, each ejection insert is matched with the corresponding through hole, the ejection inserts are arranged in the through holes, at the moment, the first cavities are matched with the second cavities to form the third cavities, then moxa sticks are put into the third cavities, the pressing plate and the mold body are covered and combined to tightly press the moxa sticks in the third cavities, after the pressing plate is opened, molded moxa cones are obtained, and finally, the ejection inserts are moved upwards, the molded moxa cones are ejected by the ejection inserts, so that the molded moxa sticks are convenient to be demolded, operators are convenient to take out the moxa cones after the mold stripping, in addition, the moxa cones are not easy to damage in the demolding process, and the integrity of the moxa cones is ensured.

According to some embodiments of the utility model, the through hole is a secondary stepped hole, the ejection insert comprises a core and a push rod arranged at the bottom of the core, the core is matched with a large hole of the secondary stepped hole, and the push rod is matched with a small hole of the secondary stepped hole.

The beneficial effects are that: through making the through-hole be the second grade shoulder hole, ejecting mold insert includes core and ejector pin, from last down when putting ejecting mold insert into the second grade shoulder hole, the ejector pin penetrates the macropore and the aperture of second grade shoulder hole in proper order, the bottom surface of core and the macropore diapire butt of second grade shoulder hole to, make the second grade shoulder hole can support ejecting mold insert, ejecting mold insert is even with the through-hole atress, guarantees the structural stability of moxa cone mould.

According to some embodiments of the utility model, the bottom of the ejector rod protrudes out of the bottom surface of the die body, and the base is provided with an opening for accommodating the ejector rod.

The beneficial effects are that: through making ejector pin bottom protrusion mould body bottom surface, the base is provided with the opening, when making the moxa cone, mould body is kept flat on the base, put into corresponding through-hole with a plurality of ejecting mold inserts after, the ejector pin of ejecting mold insert pierces into the opening, the opening can prevent that base and ejector pin from taking place to interfere, after the moxa cone shaping, take out the moxa cone mould, then keep flat on even desktop, ejector pin bottom earlier with desktop butt, then, the mould body continues down to remove under the effect of self gravity, until mould body bottom and desktop butt, at this moment, a plurality of ejecting mold inserts jack-up a plurality of moxa cones after the shaping simultaneously, thereby be convenient for a plurality of moxa cones drawing of patterns simultaneously, further improve the production efficiency of moxa cone.

According to some embodiments of the utility model, the first cavity is of an inverted circular truncated cone structure, the second cavity is of an inverted circular cone structure, and the bottom of the first cavity is matched with the top of the second cavity.

The beneficial effects are that: through making first die cavity be the inverted cone structure, the second die cavity is the inverted cone structure, first die cavity bottom and second die cavity top assorted, the diameter at inverted cone top in messenger's first die cavity and the second die cavity in inverted cone bottom equals for the third die cavity that first die cavity and second die cavity cooperation formed is great inverted cone structure, thereby, make the moxa cone after the shaping be conical, when using the moxa cone, first ignite the cone tip of moxa cone, make the moxa cone easier to ignite, moreover, the moxa cone firepower is strengthened gradually when burning, promote the treatment.

According to some embodiments of the utility model, the bottom of the pressing plate is provided with a plurality of cylindrical pressing blocks, the top of the first cavity is provided with a round hole matched with the cylindrical pressing blocks, and the bottom of the round hole is matched with the top of the inverted circular truncated cone structure.

The beneficial effects are that: through setting up cylindrical briquetting and round hole, during the preparation, with moxa filling up third die cavity and round hole, then, aim at corresponding round hole with a plurality of cylindrical briquetting in the clamp plate, compress tightly the clamp plate with force, make the briquetting move down, make moxa gather to the third die cavity to, make the moxa cone compaction after the shaping complete, be difficult for loosening.

According to some embodiments of the utility model, one side of the pressing plate is hinged with one side of the die body, and the other side of the pressing plate is detachably connected with the other side of the die body.

The beneficial effects are that: through making clamp plate one side articulated with mould body one side, the clamp plate opposite side can be dismantled with mould body opposite side and be connected, upset clamp plate can close or open clamp plate and mould body lid to, cylindrical briquetting can both aim at corresponding round hole when can guaranteeing the clamp plate to cover at every turn, reduces the time of adjustment clamp plate position.

According to some embodiments of the utility model, one side of the pressing plate is connected with one side of the die body through a hinge, and the other side of the pressing plate is connected with the other side of the die body through a spring buckle.

The beneficial effects are that: through setting up hinge and snap fastener, on the one hand, the hinge can make and rotate smoothly between clamp plate and the mould body to, make and reach quick lid between clamp plate and the mould body and close or open, on the other hand, snap fastener can be fast with clamp plate and the tight knot of mould body together, under snap fastener's elasticity effect, can make clamp plate and mould body keep inseparable state for a long time after buckling, make cylindrical briquetting on the clamp plate remain the state of sticis to the moxa in third die cavity and the round hole all the time, prevent to turn back loose, thereby, guarantee that the moxa cone after the shaping is tight, moreover, save operating personnel's strength.

According to some embodiments of the present utility model, the mold body and the pressing plate are both in a cuboid structure, the plurality of first cavities are sequentially arranged along the length direction of the mold body, and the hinge and the spring buckle are respectively arranged on two longer sides of the pressing plate and the mold body.

The beneficial effects are that: through making mould body and clamp plate be the cube structure, hinge and spring hasp set up respectively in the longer both sides of clamp plate and mould body, when making moxa cone, a plurality of cylindrical briquetting on the clamp plate can compress tightly the moxa in corresponding third die cavity and the round hole simultaneously, makes the moxa atress in each third die cavity and the round hole even to, can make the moxa cone specification after every shaping uniform, compact state is unanimous, satisfies the standardization of moxa cone shaping.

According to some embodiments of the utility model, two sides of the top of the base are provided with limiting blocks, the limiting blocks are used for limiting the edge of the die body, and the opening is located between the two limiting blocks.

The beneficial effects are that: through setting up two stopper, two stopper can carry out spacingly to mould body edge to, make each time make Ai Dashi, the ejector pin bottom can both accurately pierce into the opening.

According to some embodiments of the utility model, the base bottom is provided with support columns.

The beneficial effects are that: through setting up the support column, can support the base, make the base bottom have certain avoidance space, prevent that the ejector pin bottom from crossing behind the opening and interfering with the desktop, saved the material cost of base.

Additional aspects and advantages of the utility model will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the utility model.

Drawings

The foregoing and/or additional aspects and advantages of the utility model will become apparent and may be better understood from the following description of embodiments taken in conjunction with the accompanying drawings in which:

fig. 1 is a schematic perspective view of a moxa cone former according to an embodiment of the present utility model;

FIG. 2 is an exploded view of FIG. 1;

FIG. 3 is a schematic diagram of the front structure of FIG. 1;

fig. 4 is a cross-sectional view of fig. 3.

Reference numerals: 100-base, 110-moxa cone mould, 120-mould body, 130-ejecting mold insert, 140-first die cavity, 150-through hole, 160-second die cavity, 170-third die cavity, 180-clamp plate, 190-core, 200-ejector pin, 210-opening, 220-briquetting, 230-round hole, 240-hinge, 250-snap fastener, 260-stopper, 270-support column.

Detailed Description

Embodiments of the present utility model are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative only and are not to be construed as limiting the utility model.

In the description of the present utility model, it should be understood that references to orientation descriptions such as upper, lower, front, rear, left, right, etc. are based on the orientation or positional relationship shown in the drawings, are merely for convenience of description of the present utility model and to simplify the description, and do not indicate or imply that the apparatus or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present utility model.

In the description of the present utility model, a number means one or more, a number means two or more, and greater than, less than, exceeding, etc. are understood to not include the present number, and above, below, within, etc. are understood to include the present number. The description of the first and second is for the purpose of distinguishing between technical features only and should not be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated or implicitly indicating the precedence of the technical features indicated.

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

A moxa cone former according to an embodiment of the present utility model is described below with reference to the accompanying drawings.

Referring to fig. 1 to 4, a moxa cone former according to an embodiment of the present utility model includes a base 100, a moxa cone mold 110, and a pressing plate 180.

In this arrangement, the moxa cone mold 110 is disposed on the base 100, and the platen 180 is disposed on top of the moxa cone mold 110.

Structurally, the moxa cone mold 110 comprises a mold body 120 and a plurality of ejection inserts 130, a plurality of first cavities 140 which are opened upwards are formed in the top of the mold body 120, through holes 150 are formed in the mold body 120, the through holes 150 are communicated with the first cavities 140 and the bottom of the mold body 120, the ejection inserts 130 are arranged in the through holes 150, the ejection inserts 130 are accommodated in the through holes 150 and ejected upwards, a second cavity 160 is formed in the top of the ejection insert 130, and the first cavities 140 and the second cavities 160 are matched to form a third cavity 170.

When moxa cones are manufactured, the mold body 120 is placed on the base 100, the plurality of ejection inserts 130 are respectively placed into the plurality of through holes 150 from top to bottom, each ejection insert 130 is matched with the corresponding through hole 150, the ejection inserts 130 are arranged in the through holes 150, at the moment, the first cavity 140 and the second cavity 160 are matched to form a third cavity 170, moxa sticks are placed in the third cavity 170, the pressing plate 180 and the mold body 120 are covered, the pressing plate 180 tightly presses the moxa sticks in the third cavity 170, the pressure is maintained for a certain time, then the pressing plate 180 is opened to obtain a plurality of molded moxa sticks, finally, the plurality of ejection inserts 130 are moved upwards, each ejection insert 130 jacks up the corresponding moxa sticks, so that molded moxa sticks are convenient to be demolded, an operator can conveniently take out the moxa sticks after demolding, moreover, the moxa sticks are not easy to damage in the demolding process, and the integrity of the moxa sticks is ensured.

Referring to fig. 4, in some preferred embodiments, the through hole 150 is a secondary stepped hole, and the ejection insert 130 includes a core 190 and a ram 200 disposed at the bottom of the core 190, the core 190 being engaged with a large hole of the secondary stepped hole, and the ram 200 being engaged with a small hole of the secondary stepped hole.

It can be appreciated that by making the through hole 150 a secondary stepped hole, the ejection insert 130 includes the core 190 and the ejector rod 200, when the ejection insert 130 is put into the secondary stepped hole from top to bottom, the ejector rod 200 sequentially penetrates into the large hole and the small hole of the secondary stepped hole, and the bottom surface of the core 190 is abutted with the bottom wall of the large hole of the secondary stepped hole, so that the secondary stepped hole can support the ejection insert 130, the ejection insert 130 and the through hole 150 are stressed uniformly, and structural stability of the moxa cone mold 110 is ensured.

In some preferred embodiments, the bottom of the ejector pin 200 protrudes from the bottom surface of the mold body 120, and the base 100 is provided with an opening 210 for receiving the ejector pin 200 therethrough.

It can be appreciated that, by making the bottom of the ejector pin 200 protrude out of the bottom surface of the mold body 120, the base 100 is provided with the opening 210, when the moxa cone is manufactured, the mold body 120 is horizontally placed on the base 100, after the plurality of ejection inserts 130 are placed into the corresponding through holes 150, the ejector pin 200 of the ejection insert 130 penetrates into the opening 210, the opening 210 can prevent the interference between the base 100 and the ejector pin 200, when the moxa cone is molded, the moxa cone mold 110 is taken out and horizontally placed on a flat tabletop, the bottom of the ejector pin 200 is firstly abutted against the tabletop, then the mold body 120 continuously moves downwards under the action of gravity until the bottom of the mold body 120 is abutted against the tabletop, at this time, the plurality of ejection inserts 130 jack up a plurality of molded moxa cones at the same time, thereby facilitating the simultaneous demolding of a plurality of moxa cones and further improving the production efficiency of the moxa cones.

In some preferred embodiments, the first cavity 140 has an inverted conical configuration and the second cavity 160 has an inverted conical configuration, with the bottom of the first cavity 140 matching the top of the second cavity 160.

It can be appreciated that by making the first cavity 140 an inverted cone structure, the second cavity 160 an inverted cone structure, the bottom of the first cavity 140 is matched with the top of the second cavity 160, so that the diameter of the bottom of the inverted cone in the first cavity 140 is equal to that of the top of the inverted cone in the second cavity 160, and the third cavity 170 formed by matching the first cavity 140 with the second cavity 160 is a larger inverted cone structure, so that the moxa cone after molding is conical, when using the moxa cone, the cone tip of the moxa cone is ignited first, so that the moxa cone is easier to ignite, and when burning, the firepower of the moxa cone is gradually enhanced, thereby improving the treatment effect.

In some preferred embodiments, a plurality of cylindrical pressing blocks 220 are arranged at the bottom of the pressing plate 180, a round hole 230 matched with the cylindrical pressing blocks 220 is arranged at the top of the first cavity 140, and the bottom of the round hole 230 is matched with the top of the inverted truncated cone structure.

It can be appreciated that by arranging the cylindrical pressing blocks 220 and the round holes 230, during manufacturing, moxa is filled in the third cavity 170 and the round holes 230, then, a plurality of cylindrical pressing blocks 220 in the pressing plate 180 are aligned with the corresponding round holes 230, and the pressing plate 180 is pressed hard to enable the pressing blocks 220 to move downwards, so that the moxa is gathered towards the third cavity 170, and the molded moxa cone is compact and complete and is not easy to loosen.

In some preferred embodiments, one side of the platen 180 is hinged to one side of the mold body 120, and the other side of the platen 180 is removably connected to the other side of the mold body 120.

It can be appreciated that by hinging one side of the pressing plate 180 to one side of the die body 120, the other side of the pressing plate 180 is detachably connected to the other side of the die body 120, and turning the pressing plate 180 over, the pressing plate 180 can be covered or opened with the die body 120, so that the cylindrical pressing block 220 can be aligned with the corresponding circular hole 230 each time the pressing plate 180 is covered, and the time for adjusting the position of the pressing plate 180 is reduced.

In some preferred embodiments, one side of the platen 180 is connected to one side of the mold body 120 by a hinge 240 and the other side of the platen 180 is connected to the other side of the mold body 120 by a snap 250.

It can be appreciated that by arranging the hinge 240 and the snap fastener 250, on one hand, the hinge 240 can enable the platen 180 and the mold body 120 to rotate smoothly, so that the platen 180 and the mold body 120 can be covered or opened quickly, on the other hand, the snap fastener 250 can enable the platen 180 and the mold body 120 to be fastened together quickly, under the elastic force of the snap fastener 250, the platen 180 and the mold body 120 can be kept in a tight state for a long time after being fastened, and the cylindrical pressing block 220 on the platen 180 always keeps a tight state for moxa in the third cavity 170 and the round hole 230, so that the moxa cone is prevented from being loosened, thus ensuring the tightness of the molded moxa cone, and saving the force of operators.

In some preferred embodiments, the mold body 120 and the pressing plate 180 are both rectangular structures, and the plurality of first cavities 140 are sequentially arranged along the length direction of the mold body 120, and the hinge 240 and the snap 250 are respectively arranged on two longer sides of the pressing plate 180 and the mold body 120.

It can be appreciated that, by making the mold body 120 and the pressing plate 180 have a square structure, the hinge 240 and the snap fastener 250 are respectively disposed on two sides of the pressing plate 180 and the mold body 120, and when making moxa cones, the cylindrical pressing blocks 220 on the pressing plate 180 can simultaneously press the moxa sticks in the corresponding third cavity 170 and the round hole 230, so that the moxa sticks in each third cavity 170 and the round hole 230 are stressed uniformly, and therefore, the specification of each molded moxa cone is uniform, the compaction state is uniform, and the standardization of moxa cone molding is satisfied.

In some preferred embodiments, two sides of the top of the base 100 are provided with limiting blocks 260, the limiting blocks 260 are used for limiting the edge of the die body 120, and the opening 210 is located between the two limiting blocks 260.

It can be appreciated that by providing two stoppers 260, the two stoppers 260 can limit the edges of the die body 120, so that the bottom of the ejector rod 200 can accurately penetrate into the opening 210 each time the die body is manufactured Ai Dashi.

In some preferred embodiments, the base 100 is provided with support columns 270 at the bottom.

It can be appreciated that by providing the support columns 270, the base 100 can be supported, so that the bottom of the base 100 has a certain clearance space, the bottom of the ejector rod 200 is prevented from interfering with the tabletop after passing through the opening 210, and the material cost of the base 100 is saved.

In the description of the present specification, reference to the terms "one embodiment," "some embodiments," "illustrative embodiments," "examples," "specific examples," or "some examples," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the utility model. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The embodiments of the present utility model have been described in detail with reference to the accompanying drawings, but the present utility model is not limited to the above embodiments, and various changes can be made within the knowledge of one of ordinary skill in the art without departing from the spirit of the present utility model.

Claims (10)

1. A moxa cone former, comprising:

a base (100);

moxa cone mould (110) are arranged on the base (100), and comprise a mould body (120) and a plurality of ejection inserts (130), wherein a plurality of first cavities (140) which are opened upwards are arranged at the top of the mould body (120), through holes (150) are formed in the mould body (120), the through holes (150) are communicated with the first cavities (140) and the bottom of the mould body (120), the ejection inserts (130) are arranged in the through holes (150), the ejection inserts (130) are ejected upwards in the through holes (150), a second cavity (160) is formed in the top of the ejection inserts (130), and the first cavities (140) and the second cavities (160) are matched to form a third cavity (170);

and the pressing plate (180) is covered with the top of the die body (120).

2. The moxa cone former according to claim 1, wherein the through hole (150) is a secondary stepped hole, the ejection insert (130) comprises a core (190) and a plunger rod (200) disposed at the bottom of the core (190), the core (190) is matched with a large hole of the secondary stepped hole, and the plunger rod (200) is matched with a small hole of the secondary stepped hole.

3. The moxa cone former according to claim 2, wherein the bottom of the ejector rod (200) protrudes out of the bottom surface of the die body (120), and the base (100) is provided with an opening (210) for accommodating the ejector rod (200) to penetrate.

4. The moxa cone former according to claim 1, wherein the first cavity (140) has an inverted conical structure, the second cavity (160) has an inverted conical structure, and the bottom of the first cavity (140) is matched with the top of the second cavity (160).

5. The moxa cone former according to claim 4, wherein a plurality of cylindrical pressing blocks (220) are arranged at the bottom of the pressing plate (180), a round hole (230) matched with the cylindrical pressing blocks (220) is formed at the top of the first cavity (140), and the bottom of the round hole (230) is matched with the top of the inverted truncated cone structure.

6. The moxa cone former according to claim 1, wherein one side of the pressure plate (180) is hinged to one side of the mold body (120), and the other side of the pressure plate (180) is detachably connected to the other side of the mold body (120).

7. The moxa cone former according to claim 6, wherein one side of the pressure plate (180) is connected to one side of the mold body (120) by a hinge (240), and the other side of the pressure plate (180) is connected to the other side of the mold body (120) by a snap-lock (250).

8. The moxa cone former according to claim 7, wherein the mold body (120) and the pressing plate (180) are both in a rectangular parallelepiped structure, the plurality of first cavities (140) are sequentially arranged along the length direction of the mold body (120), and the hinge (240) and the snap fastener (250) are respectively arranged on two longer sides of the pressing plate (180) and the mold body (120).

9. A moxa cone former according to claim 3, wherein two sides of the top of the base (100) are provided with limiting blocks (260), the limiting blocks (260) are used for limiting the edge of the die body (120), and the opening (210) is located between the two limiting blocks (260).

10. A moxa cone former according to claim 1, wherein the base (100) is provided with support posts (270) at the bottom.

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