JP2751097B2 - Die-casting mechanism, and method of manufacturing solidified-formed article using the mold-flowing mechanism to produce a solidified formed article having a predetermined mixed pattern - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is used for manufacturing a solid-formed article having a predetermined mixed pattern, and is a mold-flow mechanism for pouring each viscous fluid into a predetermined unit-forming mold, and the mold-flow mechanism. The present invention relates to a method of manufacturing a solidified formed article for manufacturing a solidified formed article having a predetermined mixed pattern using a mechanism.

[0002]

2. Description of the Related Art Conventionally, in the production of solidified articles formed from a viscous fluid, for example, in the production of solidified chocolate, the content of the solidified chocolate is uniformly stored in a storage tank storing liquid chocolate by a depositor (quantitative filling machine). The production method is such that the liquid chocolate applied to the mold is weighed and poured into a desired mold while stirring so that the solid state is not collapsed. In this production method, a single solidified chocolate (solidified formed article) is used. For a predetermined unit forming die for forming a liquid, a mold flow mechanism of an embodiment in which one kind of liquid chocolate is guided by a single partitioned passage is adopted.

[0003]

However, when a mixed pattern is applied to the solidified chocolate, two kinds of liquid chocolates are stored together in one storage tank, and then each liquid chocolate is weighed in a mixed state. A mixed pattern is formed by a method of pouring the weighed mixed liquid chocolate into a predetermined unit forming mold. As described above, the two types of liquid chocolate are preliminarily mixed before the weighing, and the amount ratio of each liquid chocolate is different for each solidified chocolate to be formed. Therefore, the solidified chocolate having a predetermined (uniform) mixed pattern is applied. There is a disadvantage that it is impossible to manufacture a (solidified formed article having a predetermined mixed pattern with two or more kinds of viscous fluids).

[0004] As another method, there is a method in which a desired liquid chocolate is previously applied to the inner surface of a chocolate mold by a brush or the like and then filled with another type of liquid chocolate by a depositor to form a mixed pattern. There is a disadvantage that this troublesome coating operation requires a great deal of time and labor. Moreover, the mixed pattern applied differs for each coated and solidified chocolate, similarly to the solidified chocolate.

[0005]

[0006] The present invention focuses on the above-mentioned disadvantages of the prior art.
However, the first purpose is to solve this.
Providing a first mold flow mechanism at least color the different two or more kinds of the viscous fluids can substantially be poured concurrently to a predetermined unit-forming at a predetermined state mixed enters the degree of Nozomu Tokoro, and the second using one type of flow mechanism, the solidified form article comprising performing a predetermined interwoven pattern blurred to the extent of Nozomu Tokoro easily, yet provides a first method of manufacturing a solidified form articles that can be precisely manufactured It is in.

A second object of the present invention is to provide a second unit capable of pouring at least two or more kinds of viscous fluids having different color tones into a predetermined unit forming mold almost simultaneously in a predetermined state further mixed to a desired degree . providing a mold flow mechanism, and the
Provided is a method of manufacturing a second solidified formed article that can easily and accurately manufacture a solid formed article formed by applying a predetermined mixed pattern blurred to a desired degree by using a second mold flow mechanism. It is in.

A third object of the present invention is to flow at least one kind of viscous fluid covered and accommodated therein and two or more kinds of viscous fluids surrounding the viscous fluid in a predetermined state in a predetermined unit forming mold. providing a third type flow mechanism capable, and using the third type flow mechanism, at least one of the viscous fluid was coated housed inside, and formed by performing predetermined interwoven pattern on its periphery It is an object of the present invention to provide a third method for manufacturing a solidified article, which can easily and accurately mass-produce the solidified article.

A fourth object of the present invention is to provide a state in which two or more kinds of viscous fluids are merged and joined together so as to cover and house at least one kind of viscous fluid therein, or providing a fourth type flow mechanism capable of pouring a predetermined unit-forming at a predetermined state mixed enters, and using the fourth type flow mechanism, covering at least one viscous fluid inside It is an object of the present invention to provide a fourth method for producing a solid-formed article which can be easily and accurately mass-produced and formed into a solid-formed article having a predetermined mixed pattern which is accommodated therein and has an appropriate haze.

A fifth object of the present invention is to provide at least one kind of viscous fluid in a predetermined state in which two or more kinds of viscous fluids are further mixed to a desired extent so as to cover and house therein at least one kind of viscous fluid. providing a fifth <br/> type flow mechanism capable of pouring a predetermined unit-forming, and using said fifth mold flow mechanism, covered accommodate at least one of the viscous fluid therein,
It is still another object of the present invention to provide a fifth method for manufacturing a solid-formed article, which can easily and accurately mass-produce a solid-formed article having a predetermined mixed pattern with a desired degree of dimming around it.

[0011]

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned object, and the gist of the present invention is to use a mold mixing mechanism and a mold mixing mechanism described below to form a predetermined mixture. A method for producing a solidified formed article having a pattern.

[0012]

[0013]

[0014] 1. The first mold flow for the first object
In order to attain the provision of a printing mechanism, at least
Prescribed mixed pattern with more than one kind of viscous fluid
Die sinker used in the manufacture of solid formed articles
Wherein a predetermined solidification formed article is formed.
Each viscous fluid measured individually into a unit forming mold
Equipped with a plurality of separate passages that guide separately
Each sending at least two kinds of viscous fluids almost simultaneously
The hole is located on a predetermined surface facing the predetermined unit forming die.
Te are disposed in any combination, also includes a non-compartmental passage communicating with a plurality of delivery holes of the compartment passages arranged in any combination, a plurality of delivery holes provided in the non-compartment passage of the predetermined type flow mechanism you characterized in that it is disposed opposite to the unit-forming it is an aspect of the present invention.

According to this aspect, the plurality of delivery holes provided in the non-compartmental passage communicating with the plurality of delivery holes of the above-mentioned sectioned passage are arranged to face the predetermined unit forming mold. can be poured into predetermined unit-forming at a predetermined state mixed enters each viscous fluid are merged in section passage suitable person.

[0016] 2. The second mold flow for the second purpose
In order to attain the provision of a printing mechanism, at least
Prescribed mixed pattern with more than one kind of viscous fluid
Die sinker used in the manufacture of solid formed articles
Wherein a predetermined solidification formed article is formed.
Each viscous fluid measured individually into a unit forming mold
Equipped with a plurality of separate passages that guide separately
Each sending at least two kinds of viscous fluids almost simultaneously
The hole is located on a predetermined surface facing the predetermined unit forming die.
Arbitrarily combined, and arbitrarily combined
Communicates with the plurality of delivery holes of the partition passage arranged
A non-compartmental passage, at least one of which is provided in the non-compartmental passage.
Two delivery holes are arranged facing the above-mentioned unit forming mold.
In the middle part of the non-compartmental passage, at least one
Perforated wall having the aperture to the other aspect of the present invention the mold flow mechanism you characterized in that provided to intersect the fluid passage direction of the non-compartment passage.

According to this aspect, the perforated wall having at least one opening is formed in the middle of the non-partitioned passage,
Since the viscous fluids are provided so as to intersect with the fluid passage direction of the non-partition passages, each viscous fluid can be poured into a predetermined unit forming mold in a predetermined state in which the viscous fluids are further mixed to a desired degree.

[0018]

[0019] 3. Third mold flow for the third purpose
In order to attain the provision of a printing mechanism, at least
Prescribed mixed pattern with more than one kind of viscous fluid
Die sinker used in the manufacture of solid formed articles
Wherein a predetermined solidification formed article is formed.
Each viscous fluid measured individually into a unit forming mold
Equipped with a plurality of separate passages that guide separately
Each sending at least two kinds of viscous fluids almost simultaneously
The hole is located on a predetermined surface facing the predetermined unit forming die.
At least one transmission
The delivery timing of the viscous fluid delivered from the hole is
The transmission timing of the viscous fluid delivered from the delivery hole
Delays the start of transmission and precedes the end of transmission.
Update the transmission timing setting maintaining means set to
To be mounted on a predetermined surface facing the predetermined unit forming die.
And the transmission timing is set by the means.
At least two types of viscous fluids surround the delivery holes
The above-mentioned other sending holes for sending are arranged in any combination.
The mold sinking mechanism is characterized in that
I do. According to this aspect, on the predetermined surface facing the predetermined unit forming die, any other delivery holes for delivering at least two kinds of viscous fluids are arbitrarily combined so as to surround the at least one delivery hole. The viscous fluid is delivered based on the delivery timing set by the delivery timing setting and maintaining means, so that at least one kind of viscous fluid is covered and accommodated therein so that two Each viscous fluid described above can be poured into a predetermined unit forming mold in a predetermined state.

[0020] 4. The fourth mold flow for the fourth object.
In order to attain the provision of a printing mechanism, at least
Prescribed mixed pattern with more than one kind of viscous fluid
Die sinker used in the manufacture of solid formed articles
Wherein a predetermined solidification formed article is formed.
Each viscous fluid measured individually into a unit forming mold
Equipped with a plurality of separate passages that guide separately
Each sending at least two kinds of viscous fluids almost simultaneously
The hole is located on a predetermined surface facing the predetermined unit forming die.
Arbitrarily combined, and arbitrarily combined
Communicates with the plurality of delivery holes of the partition passage arranged
A non-compartmental passage, at least one of which is provided in the non-compartmental passage.
Two delivery holes are arranged facing the above-mentioned unit forming mold.
Of the viscous fluid delivered from at least one delivery hole.
The delivery timing is controlled by the viscous flow delivered from each of the other delivery holes.
Delay the start of the transmission with respect to the transmission timing of the body,
And the sending tie set to precede the sending end
A predetermined unit forming mold
On the predetermined surface facing the
Small so as to surround the delivery hole where
Each of the other delivery holes for delivering at least two types of viscous fluids is optional.
Die sinkers characterized by being arranged in any combination
The structure is another gist of the present invention. According to this aspect, at least one delivery hole provided in the non-compartment passage communicating with the plurality of delivery holes of the compartment passage provided in any combination in the mold flow mechanism faces a predetermined unit forming mold. Since at least one type of viscous fluid is covered and accommodated in the interior, two or more types of viscous fluids are merged together in a predetermined state, The mixture can be poured into a predetermined unit forming mold in a predetermined state.

[0021] 5. Fifth mold flow for the fifth object
In order to attain the provision of a printing mechanism, at least
Prescribed mixed pattern with more than one kind of viscous fluid
Die sinker used in the manufacture of solid formed articles
Wherein a predetermined solidification formed article is formed.
Each viscous fluid measured individually into a unit forming mold
Equipped with a plurality of separate passages that guide separately
Each sending at least two kinds of viscous fluids almost simultaneously
The hole is located on a predetermined surface facing the predetermined unit forming die.
Arbitrarily combined, and arbitrarily combined
Communicates with the plurality of delivery holes of the partition passage arranged
A non-compartmental passage, at least one of which is provided in the non-compartmental passage.
Two delivery holes are arranged facing the above-mentioned unit forming mold.
In the middle part of the non-compartmental passage, at least one
The perforated wall having an opening of
Provided crosswise and delivered from at least one delivery hole
The delivery timing of the viscous fluid is controlled from the other delivery holes.
Delivery start of the viscous fluid
Set to delay and end the transmission end earlier
Transmission timing setting maintaining means, wherein the predetermined
On the predetermined surface facing the unit forming die,
Encloses the above-mentioned sending hole where the sending timing is set.
As described above, at least two other viscous fluids are delivered.
The discharge holes are arranged in any combination.
Another aspect of the present invention is a mold sink mechanism. According to this aspect
In this case, in the middle of the non-partitioned passage in the mold flow mechanism, a perforated wall having at least one opening is provided so as to intersect with the fluid passage direction of the comparison passage. Two or more types of viscous fluids can be poured around the viscous fluid into a predetermined unit forming mold in a predetermined state in which the viscous fluids are further mixed to a desired degree so as to cover and accommodate the viscous fluid.

[0022] 6. In the first and second objects,
A method for producing the first and second solidified articles should be provided.
A method of manufacturing a solidified article formed by applying a predetermined mixed pattern with two or more types of viscous fluids using the mold flow mechanism according to 1 or 2 above , wherein each viscous fluid is individually measured. And a predetermined amount of each viscous fluid measured individually in the step is guided by each passage provided in the mold flow mechanism described in 1 or 2 above , and is disposed to face a predetermined unit forming mold. Sending out substantially simultaneously from the delivery hole,
Another aspect of the present invention is a method for manufacturing a solidified formed article, comprising: receiving a viscous fluid sent in the step in a predetermined unit forming mold and solidifying and forming the same.

[0023]

According to this aspect, since the to deliver a plurality of delivery holes of non-compartmental passage communicating with a plurality of delivery holes of the compartment passages arranged in any combination, given that blurred to an appropriate person Can be easily and accurately mass-produced.

Further, since the to deliver the viscous fluid through the perforated wall having at least one aperture provided to intersect the fluid passage direction of the non-compartment passage in middle portion of the non-compartmental passage, the desired degree of It is possible to easily and accurately mass-produce a solidified article formed by applying a predetermined mixed pattern having a blurred pattern.

[0027] 7. The third of the above third to fifth objects
To achieve the provision of a fifth method for producing a solidified formed article,
Using any one of the mold sink mechanisms described in the above 3 to 5,
A method for producing a solidified article formed by applying a predetermined mixed pattern with two or more types of viscous fluids, comprising the steps of individually measuring each viscous fluid, and a predetermined amount of each viscous fluid individually measured in the step. The fluid may be any of those described in 3 to 5 above.
Guided by the respective passages provided in the first mold sink mechanism ,
A step of sending out the viscous fluid sent out in the step based on the sending timing set by the sending timing setting maintaining means from a sending hole arranged opposite to the predetermined unit forming mold; Another aspect of the present invention is a method for producing a solidified article, comprising: receiving in a mold and solidifying.

According to this aspect, on the predetermined surface facing the predetermined unit forming mold, the at least one delivery hole, and at least two types arranged in any combination so as to surround the delivery hole. from every other delivery hole for delivering viscous fluid, a viscous fluid, and sent on the basis of the transmission timing set by said transmission timing setting maintaining means, and receiving in a unit form type Jo Tokoro, so as to solidify form As a result, it is possible to easily and accurately mass-produce a solid formed article in which at least one kind of viscous fluid is coated and accommodated inside and a predetermined mixed pattern is formed around the viscous fluid.

Further, the delivery timing set by the delivery timing setting maintaining means through the non-compartment passage communicating with each of the other delivery holes for delivering at least two kinds of viscous fluids arranged in any combination. sent on the basis of, accepted in a unit form type Jo Tokoro. Thus solidified form, at least one of the viscous fluid was coated housed inside, and a predetermined interwoven pattern on its periphery or a suitable umbrella, It is possible to easily and accurately mass-produce the solidified formed article having the predetermined mixed pattern.

Furthermore, the viscous fluid through the perforated wall provided in the non-compartment passage sent based on the transmission timing set by said transmission timing setting maintaining means, and receiving in Jo Tokoro units forming type, solidified form As a result, it is possible to easily and accurately mass-produce a solid-formed article in which at least one viscous fluid is coated and accommodated inside and a predetermined mixed pattern is formed around the viscous fluid to a desired degree. it can.

[0030]

The Detailed Description of the Invention The present two or more viscous or granular material even without less of color tone different in the invention, the nature of the viscosity or the like may be further different.

The predetermined mixed pattern is defined as a striped pattern of a viscous fluid applied to at least a part of a solidified formed article, or a striped pattern of two or more kinds of viscous fluids at a specific pattern boundary such as a checkered pattern. Alternatively, in addition to an embodiment in which the solidification-formed article is partially or wholly marble-patterned, it includes an embodiment in which the solidification-formed article is mixed and mixed.

As the plurality of partition passages for individually guiding at least two kinds of viscous fluids, two or more independent passages and / or branched passages are arbitrarily selected and provided. be able to. Here, the provision of two or more partition passages and / or branching means that, for each viscous fluid, two or more partition passages are provided as respective partition passages for guiding each viscous fluid. A mode in which two or more partition passages are provided as the partition passages for guiding the viscous fluid, and a branched partition passage is provided as the partition passage for guiding the other viscous fluid, It means that an appropriate one can be adopted from among a mode in which branch paths are provided as branch paths and a mode in which these modes are arbitrarily combined.

[0033] The two or more kinds of viscous fluids, which are provided in each of the divided passages and are almost simultaneously delivered, are arranged in any combination on a predetermined surface facing the predetermined unit forming mold. Each delivery hole for delivering a fluid is regularly (for example, “AB” for two types of viscous fluids A and B).
AB… ”,“ AABAAB… ”,“ ABAABBAAA ”
BBB...) Or irregular (eg, "AA" for two types of viscous fluids A and B).
BABBAB ... "), a configuration in which the components are arranged adjacent to each other, and the combination of the configurations can be set arbitrarily. Can also be set individually or unified and arbitrarily. Here, the unit forming mold refers to a mold for forming a solidified product itself.

In the present invention, the non-compartmental passage is defined as
It refers to one that collectively guides the viscous fluids delivered from the respective delivery holes connected to at least two delivery holes that deliver different viscous fluids to the unit forming type. By adopting a mode in which the inner diameter is gradually narrowed and tapered toward the front end of the viscous fluid in the passage direction of the viscous fluid as the non-compartmental passage, the different viscous fluids delivered from the delivery holes of the compartmentalized passages are merged to each other. It can be mixed. In this non-compartmental passage, similarly to the compartmental passage, an arbitrary hole shape, the number of perforations, etc. can be set. In addition, a plurality of non-compartmental passages can be provided in parallel or in series It is also possible to use arbitrarily in combination, specifically, a mode in which a perforated wall is provided in the middle of the non-partitioned passage so as to intersect with the fluid passage direction of the viscous fluid, According to this aspect, a predetermined (uniform) mixed pattern can be appropriately blurred in accordance with the combination and applied to each solidified formed article.

Further, as the means for maintaining the delivery timing setting in the present invention, for example, a means for setting and maintaining the delivery timing of each viscous fluid in a depositor for measuring each viscous fluid, as well as well-known appropriate means are employed. be able to.

In the present invention, the solidified article and the viscous fluid to be manufactured are chocolate, ice confectionery, jelly confectionery, butter, cheese, and other foods that have been liquid but have been cooled or heated to be solid. Something that can solidify is conceivable. In particular, for food products as described above, if the mold sink mechanism of the present invention and the manufacturing method are adopted,
It is possible to easily and accurately mass-produce high-quality solidified foods that are stable visually and tastely (quality).

[0037]

Embodiments of the present invention will be described below with reference to the accompanying drawings, but the present invention is not limited to these embodiments.

[0038]

Embodiment 1 FIGS. 1 (a) and 1 (b) are exploded schematic perspective views showing an example of a mold casting mechanism of the present invention, and FIG. 1 (c) is a unit forming mold for forming a single solidified article. FIG. 3 is a schematic perspective view showing an example of FIG. 2A is a longitudinal sectional view taken along line 2a-2a in FIG. 1A, and FIG. 2B is 2b-2b in FIG.
It is a longitudinal cross-sectional view along a line.

The mold-flowing mechanism according to the present invention is a mold-flowing mechanism used for producing solidified chocolate (solidified formed article) in which a predetermined mixed pattern is formed by two kinds of liquid chocolates A and B (viscous fluid). So, Figure 1
As shown in FIG. 2, a predetermined unit forming mold 30 (FIG. 1 (c)) for forming a single solidified chocolate has a predetermined amount individually measured by a depositor (not shown) in advance. Partition nozzles 10 for individually guiding the liquid chocolates A and B, respectively, and delivery holes 11a 'to a plurality of partition passages 11 and 12 (FIGS. 2A and 2B) penetrating the partition nozzle 10. 11h ′, 12a ′ to 12h ′, a non-compartmental nozzle 20 (FIG. 1 (b)) that collectively guides the liquid chocolates A and B guided by the compartmental passages 11 and 12 to the unit forming die 30. )).

The plurality of partition passages 11 penetrating through the partition nozzle 10 (FIG. 2B) are passages for guiding the liquid chocolate A to the unit forming mold 30, and each of the partition passages 11
Is the liquid chocolate A measured by the depositor
Receiving holes 11a to 11h for receiving the
A delivery hole 11a 'for sending the liquid chocolate A received in 1a to 11h to the unit forming mold 30 substantially simultaneously.
To 11h '. The plurality of partition passages 12 penetrating the partition nozzle 10 (FIG. 2A) are passages for guiding the liquid chocolate B to the unit forming mold 30, similarly to the partition passages 11, and Passage 12 has receiving holes 12a to 12h for receiving liquid chocolate B measured by the depositor, and receiving holes 12a to 1h.
It has delivery holes 12a 'to 12h' for delivering the liquid chocolate B received in 2h to the unit forming mold 30. Delivery holes 11a 'to 11 of the partition passage 11
h ', and the delivery holes 12a' to 12 of the partition passage 12
h ′ are arranged so as to be arranged alternately in a ring on a predetermined surface facing the unit forming die 30, and the delivery holes 11 a ′ to 11 h ′, 1, which are arranged in any combination thereof.
From 2a 'to 12h', each of the liquid chocolates A and B is delivered almost simultaneously in a predetermined state. As a partition nozzle for individually guiding each of the liquid chocolates A and B to the unit forming die 30, each of the liquid chocolates A and B is replaced with each of the partition passages 11 and 12 of the partition nozzle instead of the partition nozzle 10. The guide is guided by another section passage or the like branched before guiding to the section nozzle, or as described later, in the section nozzle in the section nozzle,
12 itself (FIGS. 3A and 3B)
See also).

The above-described delivery holes 1 of the partition passages 11 and 12
As shown in FIG. 1B, the non-partitioned nozzles 20 connected to 1a 'to 11h' and 12a 'to 12h' are formed as a tapered cylindrical body having an inverted truncated cone shape. Delivery holes 11a 'to 11h', 12a 'of the partition passages 11, 12
To 12h 'are received in the receiving holes 21a, and the received liquid chocolates A and B are collected by the non-partitioning passage 21 and sent out from the transmitting holes 21a' provided at the lower end thereof. And unit forming mold 3
0. As a non-compartmental nozzle for guiding the liquid chocolates A and B together to the unit forming mold 30, instead of the non-compartmental nozzle 20, FIG.
As shown in (a) to (c), other non-compartmental nozzles 40 described later can be adopted, whereby the liquid chocolate A, which is delivered in a predetermined state from the compartmental nozzle 10, can be used.
B can be sent out in a predetermined state where they are combined together or in an appropriate mixed state.

As described above, in the mold flow mechanism of the present embodiment, each of the liquid chocolates A and B measured in advance by the depositor (not shown) receives the receiving holes 11 a of the partitioning passages 11 and 12 in the partitioning nozzle 10. ~ 11h, 1
After being received in 2a to 12h, a plurality of delivery holes 11a 'to 11h', 12a 'arranged to be arranged alternately in a ring on a predetermined surface facing the unit forming die 30.
~ 12h ', and the liquid chocolates A and B sent out are gathered by the non-partitioning passage 21 of the non-partitioning nozzle 20, and then guided to the storage part 31 of the unit forming die 30. .

In order to manufacture a solidified chocolate (solidified formed article) in which a predetermined mixed pattern is formed by using two types of liquid chocolates A and B (viscous fluid) by using the above-mentioned mold flow mechanism, first, each liquid chocolate A, B are individually weighed by a depositor (not shown), and then the weighed predetermined amounts of the respective liquid chocolates A and B are individually guided by the respective partition passages 11 and 12 of the partition nozzle 10 to form the unit forming die 30. The partition passages 11 and 12 are arranged so as to be arranged alternately in an annular shape on a predetermined surface facing the
The liquid chocolates A and B delivered from the delivery holes 11 a ′ to 11 h ′ and 12 a ′ to 12 h ′ are collectively guided by the non-compartment passage 21 of the non-compartment nozzle 20, and are accommodated in the unit forming die 30. The solid is formed in the unit forming die 30. Thus, solidified chocolate (solidified formed article) having a predetermined mixed pattern is manufactured. Note that a cooling device or the like can be separately used during the above-described solidification, and a heating device or the like can be used according to the viscous fluid involved in the solidification.

Further, in the mold flow mechanism according to the present invention, the non-partition nozzle 2 in the mold flow mechanism of the present embodiment is used.
It is also possible to carry out without providing 0, and according to this embodiment, blurring of the mixed pattern provided by the liquid chocolates A and B can be reduced. The non-compartmental nozzle 20
When the solidified chocolate having a predetermined mixed pattern is manufactured using the mold flowing mechanism according to the present invention in a mode in which the chocolate is not provided, the liquid chocolates A and B are first deposited into a depositor (FIG. (Not shown), and then a predetermined amount of each of the weighed liquid chocolates A and B is applied to each of the partition passages 1 of the partition nozzle 10.
1 and 12, which are individually guided by each other, and are arranged so as to be arranged alternately in a ring on a predetermined surface facing the unit forming mold 30.
h ′, 12a ′ to 12h ′, the liquid chocolates A and B poured into the container 31 of the unit forming die 30 are solidified and formed in the container 31 of the unit forming die 30. A solidified chocolate (solidified formed article) having a mixed pattern can be manufactured.

Further, in the mold flow mechanism according to the present invention, instead of the above-described section nozzle 10 (FIG. 1A), another section nozzle 10 shown in FIGS. 3A and 3B is employed. You can also. Sectional nozzle 10 shown in FIG.
Is provided with an enclosing wall 13 located outside thereof so as to surround each of the receiving holes 11a to 11h of the partitioned passage (11 (passage corresponding to 11 in FIG. 2B)). (11 (passage corresponding to 11 in FIG. 2 (b))), which are located inward from the arrangement positions of the receiving holes 11a to 11h,
A surrounding wall 14 located outside the receiving passages 12a to 12h of the partition passage (12 (passage corresponding to 12 in FIG. 2A)) is provided. If this partition nozzle 10 (FIG. 3A) is adopted, each surrounding wall 13,
Each of the liquid chocolates A and B is put into the defined area defined by 14 so that each of the liquid chocolates A and B is provided with a corresponding one of the receiving holes 11 a to 11 h and 12 a to 12 of the corresponding partitioned passage.
h, each of the delivery holes 11a 'to 11h', 1
2a 'to 12h'.

The partitioning nozzle 10 shown in FIG. 3 (b) has a partitioning passageway (11 (FIG. 2) that branches off midway and has a single receiving hole 11 'and a plurality of delivery holes 11a' to 11h '.
(A passage corresponding to 11 in (b))), a branch at an intermediate portion, a single receiving hole 12 ′ and a plurality of sending holes 12 a ′ to 1 ′.
A partition passage (12 (a passage corresponding to FIG. 2A)) having 2h ′ is provided. This partition nozzle (Fig. 3
If (b)) is adopted, the liquid chocolates A and B are put into the single receiving holes 11 'and 12' provided in each of the section passages, so that each of the sending holes 11a 'to 11h' and 12 is supplied.
a 'to 12h', can be transmitted in a predetermined state.

Further, in the mold flow mechanism according to the present invention, instead of the above-described non-compartmental nozzle 20, FIG.
Other non-partitioned nozzles 40 shown in (a) to (c) can be adopted. The non-compartmental nozzle 40 shown in FIG.
A single receiving hole 41a and three sending holes 41a ', 41
a ", 41a"', which are non-compartmental passages 41. Accordingly, the liquid chocolates A and B (viscous fluids) delivered from the compartment nozzle 10 are received in the receiving holes 41a, and then mixed and delivered. Thus, it is possible to produce solidified chocolate (solidified formed article) having a predetermined mixed pattern appropriately blurred.

The non-partitioning nozzle 40 shown in FIG. 4 (b) has a perforated wall 42 having an opening 42a in the middle of the non-partitioning passage 41 in the non-partitioning nozzle of FIG. (Viscous fluid) is a nozzle provided in such a manner as to intersect with the fluid passage direction, and
0 of each of the delivery holes 11a 'to 11h' and 12a 'to 12h'
Liquid chocolate A, B (viscous fluid) sent from
Are once collected and mixed to squeeze out, thereby enabling the production of solidified chocolate (solidified formed article) having a predetermined mixed pattern that is further blurred to a desired degree.

The non-partitioning nozzle 40 shown in FIG. 4C has a plurality (three in the figure) of apertures 42a to 42c in the middle of the partitioning passage in the non-partitioning nozzle 20 of FIG.
Are provided so as to intersect with the passage direction of the liquid chocolates A and B, and therefore, each of the delivery holes 11a 'to 11h', 1
After each of the liquid chocolates A and B sent from 2a 'to 12h' is received and mixed in the receiving hole 41a, it is sent out from the sending hole 41a 'via the openings 42a to 42c provided in the middle part. Therefore, the partition passages 11 and 12
The liquid chocolates A and B (a plurality of viscous fluids) delivered from the respective delivery holes 11a 'to 11h' and 12a 'to 12h' can be delivered in a predetermined state in which the liquid chocolates A and B (a plurality of viscous fluids) are further mixed to a desired degree. This makes it possible to produce solidified chocolate (solidified formed article) having a predetermined mixed pattern that is further blurred.

In this embodiment, the partition nozzle 10
Has been described in which the partitioning passages 11 and 12 for individually guiding the respective liquid chocolates A and B are integrally provided. However, the partitioning nozzle in the present invention is not limited to this. Such a section nozzle 10
Instead of a plurality of parts such as a nozzle member provided with a partition passage 11 mainly for guiding liquid chocolate A and another nozzle member provided with a partition passage 12 mainly for guiding liquid chocolate B According to this aspect, it is possible to form a solidified chocolate (solidified formed article) having a desired mixed pattern simply by combining the respective parts arbitrarily, and to easily remove and clean it. A remarkable effect such as the following is obtained. In addition, each passage (compartment passage 1)
1, 12 and the non-compartmental passages 21), the number of perforations can be arbitrarily determined and arranged in such a manner as to be arranged alternately in a ring as described above. The perforated shape can also be determined to any shape such as a triangular shape, a square shape, an elliptical shape, etc., and is arranged in an arbitrary arrangement such as alternately arranging the above-mentioned annular arrangement further alternately or vertically and horizontally. Or irregularly. As the predetermined unit forming mold used in the present invention, for example, a forming mold having an arbitrary shape such as a mold that imitates a desired shape can be adopted. Furthermore, the mixed pattern applied to the solidified chocolate (solidified formed article) is composed of the above-mentioned predetermined unit forming mold 30 and the liquid chocolates A and B finally disposed opposite to the unit forming mold 30. It can also be determined by setting the falling position of each liquid chocolate A, B (each viscous fluid) to be delivered in relation to the arrangement position of the delivery holes for delivering (each viscous fluid). In addition, the partition nozzle provided with the partition passage and the non-partition nozzle provided with the non-partition passage are not limited to the inverted truncated cone shape as described above, and may be set to any shape such as a rectangular shape. .

[0051]

Second Embodiment Next, another mold flow mechanism according to the present invention will be described with reference to FIGS. This mold-flowing mechanism is used to form a coated solidified chocolate (solidified article) in which a liquid chocolate C is coated and accommodated inside and a predetermined mixed pattern is formed around the liquid chocolate C by two types of liquid chocolates A and B (viscous fluid). A mold casting mechanism used in the production, which is individually weighed in advance by a depositor (not shown) into a predetermined unit forming mold 70 (FIG. 5 (c)) for forming a single solidified chocolate. A predetermined amount of each of the liquid chocolates A to C is individually prepared in the unit forming mold 70.
Nozzle 50 for guiding to the
A plurality of partition passages 51 to 53 penetrated in FIG.
(B)) Delivery holes 51a 'to 51h', 52a 'to 52
h ', 53a', the non-compartmental nozzle 60 (FIG. 5)
(B)), and the delivery hole 53 of the section passage 53 is provided.
The delivery timing of the liquid chocolate C delivered from a ′ is determined by the delivery holes 51 a ′ to 51 a of the partition passages 51 and 52.
h ′, 52a ′ to 52h ′, in order to delay the start of the delivery of the liquid chocolates A and B, which are delivered almost simultaneously from the same, and maintain the setting so that the delivery end is preceded, The liquid chocolate delivery timing is set.

The plurality of partition passages 51 penetrating the partition nozzle 50 (FIG. 6B) are passages for guiding the liquid chocolate A to the unit forming mold 70, and each of the partition passages 51
Is the liquid chocolate A measured by the depositor
Receiving holes 51a to 51h for receiving the
Delivery holes 51a'-51 for delivering liquid chocolate A received in 1a-51h to unit forming mold 70.
h ′. Further, the plurality of partition passages 52 penetrating through the partition nozzle 50 (FIG. 6A)
In the same manner as in the above, the liquid chocolate B is a passage for guiding the liquid chocolate B to the unit forming mold 70, and each partition passage 52 has receiving holes 52a to 52h for receiving the liquid chocolate B measured by the depositor, and the receiving holes 52a. And delivery holes 52a 'to 52h' for delivering the liquid chocolate B received in the unit forming mold 70 to the unit forming mold 70. The delivery holes 51a 'to 51h' of the partition passage 51 and the delivery holes 52a 'to 52h' of the partition passage 52 are arranged so as to be annularly and alternately located on a predetermined surface facing the unit forming mold 70. ing. Further, the partition nozzle 50
Is a passage for guiding the liquid chocolate C to the unit forming mold 70, a receiving hole 53a for receiving the liquid chocolate C measured by the depositor, The receiving hole 53a has a delivery hole 53a 'for delivering the received liquid chocolate C to the unit forming mold 70. Therefore, the delivery holes 51a'-5 provided in any combination are provided.
From 1h ′, 51a ′ to 51h ′, each of the liquid chocolates A and B is poured into the unit forming mold 70 in a predetermined state, and the other liquid chocolate C is poured into substantially the center of the unit forming mold 70. As a section nozzle for individually guiding each of the liquid chocolates A to C to the unit forming mold 70, instead of the section nozzle 50, each of the liquid chocolates A to C is formed by each of the section passages 51 to 53 of the section nozzle.
7 (a). In another embodiment, the guide is guided by another partition passage or the like which is branched prior to the guide, or the partition nozzles 51 to 52 themselves are branched in the partition nozzle as described later (see FIG. ) And (b)).

The delivery holes 5 of the above-described section passages 51 to 53
As shown in FIG. 5 (b), the non-partitioned nozzles 60 connected to 1a 'to 51h' and 52a 'to 52h' are formed in an inverted truncated conical shape as a cylindrical body having a tapered shape. Delivery holes 51a'-51h ', 52a' of the partition passages 51-53.
To 52h ', 53a' are received in the receiving holes 61a, and the received liquid chocolates A to C are collected by the non-compartmental passage 61, and the sending holes 61a provided at the lower end thereof. ', And guide the unit forming mold 70. Each of the liquid chocolates A to C delivered from the section nozzle is formed into the unit forming mold 7 described above.
As the non-partitioned nozzle for guiding to 0, another non-partitioned nozzle 80 described later, as shown in FIGS. 8A and 8B, may be used instead of the above-mentioned non-partitioned nozzle 60. In this way, the liquid chocolates A and B sent from the partition nozzle 50 can be sent out in a predetermined state where they are combined and put together.

Each of the liquid chocolates A to
In the casting of the C into the unit forming mold 70, the delivery timing of the liquid chocolate C is set so that the delivery start is delayed and the delivery end is preceded with respect to the delivery timing of the liquid chocolates A and B. Therefore, the bottom portion (the head portion when the mold is removed) and its surroundings of the storage unit 71 in the unit forming mold 70 and its periphery are first buried by the sent liquid chocolates A and B, and the liquid chocolate C is provided at the center thereof. , And this liquid chocolate C is finally covered with other liquid chocolates A and B.

As described above, according to the above-described mold casting mechanism of the present embodiment, each of the liquid chocolates A to C measured in advance by the depositor (not shown) is supplied to the partition nozzle 50.
At the receiving holes 51a-51 of the partitioned passages 51-53, respectively.
h, 52a to 52h, and 53a, a plurality of delivery holes 51a 'to 51 arranged so as to be arranged alternately in a ring on a predetermined surface facing the unit forming mold 70.
h ′, 52 a ′ to 52 h ′, 53 a ′, and the liquid chocolates A to C sent out are collected by the non-compartment nozzle 60, and then stored in the storage section 7 of the unit forming mold 70.
1.

Using the above-mentioned mold-flow mechanism, a coated solidified chocolate (solidified) in which liquid chocolate C is coated and accommodated inside and a predetermined mixed pattern is formed around the liquid chocolate C with two kinds of liquid chocolates A and B (viscous fluid). In manufacturing the molded article), first, each of the liquid chocolates A to C is individually weighed by a depositor (not shown), and then the weighed liquid chocolates A and B are respectively measured by the partition passages 51 and 52 of the partition nozzle 50. The liquid chocolate C is separately guided into the inner peripheral side surface of the storage portion 71 in the unit forming mold 70 by the respective components, and the measured liquid chocolate C is supplied to the unit forming mold 7 by the dividing passage 53 of the dividing nozzle 50.
It is guided so as to flow into substantially the center of the storage section 71 at 0. At this time, the delivery timing of the liquid chocolate C is
It is set such that the start of the delivery of the liquid chocolates A and B is delayed and the end of the delivery is prior to the delivery timing. Then, the delivery holes 51a 'to 51h', 52 of the partition passages 51, 52 arranged so as to be arranged alternately in a ring on a predetermined surface facing the unit forming mold 70.
Each liquid chocolate A sent from a'-52h ',
B and the delivery holes 51a 'to 51h', 52a 'to 52
Delivery hole 53a 'of the partition passage 53 arranged at the center of h'
And the liquid chocolate C sent out from the unit forming die 70
And is solidified and formed by the unit forming mold 70. In this way, coated and solidified chocolate (coated and solidified formed article) having a predetermined mixed pattern is manufactured. Note that a cooling device or the like can be separately used during the above-described solidification, and a heating device or the like can be used according to the viscous fluid involved in the solidification.

Further, in the mold flow mechanism according to the present invention, instead of the above-described section nozzle 50 (FIG. 5A), another section nozzle 50 shown in FIGS. 7A and 7B is adopted. be able to. Sectional nozzle 5 shown in FIG.
0 is provided with an enclosing wall 54 located on the outside so as to surround each of the receiving holes 51a to 51h of the partitioning passage (51 (a passage corresponding to 51 in FIG. 6B)). Passageway (51 (passage corresponding to 51 in FIG. 6B))
The receiving holes 52a to 52h and the partitioning passages (53) of the partitioning passages (52 (passage corresponding to 52 in FIG. 6A)) are located inward of the arrangement positions of the receiving holes 51a to 51h.
A surrounding wall 55 is provided outside the receiving hole 53a so as to surround the receiving hole 53a (a passage corresponding to 53 in FIGS. 6A and 6B). ) 5
2), the receiving holes 53a of the partition passage 53 are located inward from the arrangement positions of the receiving holes 52a to 52h.
Surrounding wall 56 is provided so as to surround the surrounding wall. If this section nozzle 50 (FIG. 7 (a)) is adopted, each of the liquid chocolates A to C is put into a section defined by each of the surrounding walls 54 to 56, so that each of the liquid chocolates A to C becomes a corresponding section passage. Each receiving hole 51a
To 51h, 52a to 52h, 53a,
Each delivery hole 51a'-51h ', 52a'-52h', 5
3a '.

The partitioning nozzle 50 shown in FIG. 7 (b) has a partitioning passage (see FIG. 6 (b)) which branches off midway and has a single receiving hole 51 'and a plurality of delivery holes 51a' to 51h '. 5
1) and a partitioning passage (52 (a passage corresponding to 52 in FIG. 6A)) that branches off midway and has a single receiving hole 52 ′ and a plurality of sending holes 52a ′ to 52h ′. )
And a partition passage (53 (a passage corresponding to 53 in FIGS. 6A and 6B)) having a single receiving hole 53a and a single sending hole 53a '. This partition nozzle (FIG. 7)
If (b)) is adopted, each of the liquid chocolates A to C is provided in a single receiving hole 51 ′, 52 ′, 53 ′ provided in each section passage.
, The delivery holes 51a'-51
h ', 52a' to 52h ', 53a'.

Further, in the mold flowing mechanism according to the present invention, another non-partitioning nozzle 80 shown in FIGS. 8A and 8B is replaced with the above-described non-partitioning nozzle 60 (FIG. 5B). Can be adopted. Each of the non-partitioned nozzles 80 shown in FIG. 8 (a) has a corresponding one of the delivery holes 51a 'to 52e of the partitioning passages 51 and 52 provided in the partitioning nozzle 50 shown in FIGS. A non-partitioned passage 81 is secured by a gap between two tapered cylindrical bodies disposed inside and outside in a double tube shape so as to communicate with 51h ′, 52a ′ to 52h ′.
Further, a partition passage 82 is secured by the above-described tubular body disposed inward so as to communicate with the delivery hole 53a 'of the partition passage 53 provided in the partition nozzle 50. Each delivery hole 51 a ′ of the partition passages 51 and 52 in the partition nozzle 50.
The non-compartmental passage 81 which received the liquid chocolates A and B sent from 51h 'and 52a' to 52h 'in the receiving hole 81a collectively sends out the received liquid chocolates A and B from the sending hole 81a'. On the other hand, partition nozzle 5
In the receiving passage 82a, the receiving passage 82a receives the liquid chocolate C delivered from the delivery hole 53a 'of the dividing passage 53 at 0, and sends the received liquid chocolate C as it is from the delivering hole 82a'. Each delivery hole 81
As described above, the delivery of the liquid chocolates A to C from the a ′ and 82a ′ is performed by the delivery hole 82a of the non-compartment passage 82 provided in the non-compartment nozzle 80 via the compartment passage 53 provided in the compartment nozzle 50. Of the liquid chocolate C delivered from the non-partitioning nozzle 81 is controlled by the delivery timing of the liquid chocolate C delivered from the non-partitioning passage 81 provided in the non-partitioning nozzle 80 via the partitioning passages 51 and 52 provided in the partitioning nozzle 50. The setting is such that the start of the delivery of the chocolates A and B is delayed and the end of the delivery is preceded. This non-partitioned nozzle 80 (FIG. 8A)
, Liquid chocolate A, B around the periphery so as to cover and accommodate liquid chocolate C inside
Can be poured in a predetermined state in which the liquid chocolate C is coated and accommodated therein, and the coated solidified chocolate formed by applying a predetermined mixed pattern around the liquid chocolate C can be formed more accurately. .

The non-partitioned passage 80 shown in FIG.
(A) A non-partitioned nozzle in a mode in which a perforated wall 83 is provided in a middle part of a non-partitioned passage 81 in a non-partitioned nozzle 80 so as to intersect the fluid passage direction of liquid chocolates A and B (viscous fluid). In this non-partitioned passage 81, each delivery hole 5 of the divided passages 51 and 52 in the divided nozzle 50 is provided.
After the liquid chocolates A and B delivered from 1a 'to 51h' and 52a 'to 52h' are received and merged in the receiving holes 81a, a plurality of openings (83a, 83) in the perforated wall 83 are formed.
b) etc., and the transmitted liquid chocolate A,
B are further merged and sent out from the sending hole 81a '. The delivery timing of each of the liquid chocolates A to C is the same as in the case where the above-described non-partition nozzle 80 in FIG. If this non-compartmental nozzle 80 (FIG. 8 (b)) is adopted, the liquid chocolate A,
B can be poured in a predetermined state further mixed to a desired degree, whereby the liquid chocolate C is coated and accommodated inside, and a predetermined mixed pattern further blurred to the desired degree is provided around the liquid chocolate C. Thus, the coated solidified chocolate can be easily and accurately mass-produced.

In this embodiment, as in the first embodiment, the partition nozzle 50 is integrally provided with partition passages 51 to 53 for individually guiding the liquid chocolates A to C, respectively. Although described, the present invention is not limited to this. For example, instead of the above-described section nozzle 50, a nozzle member mainly provided with a section passage 51 for guiding the liquid chocolate A, mainly Assembled from a plurality of parts, such as another nozzle member provided with a partition passage 52 for guiding the liquid chocolate B, and another nozzle member provided with a partition passage 53 mainly for guiding the liquid chocolate C. According to this aspect, the coated solidified chocolate (solidified formation) obtained by applying a desired mixed pattern only by arbitrarily combining the parts. It is possible to form a goods), remarkable advantage of the ability to clean the like removed easily obtained. In addition, each passage (compartment passages 51 to 53, 8)
2, the delivery holes provided in the non-partitioned passages 61, 81) can be arbitrarily determined in number, and can be arranged so as to be arranged alternately in a ring as described above. The perforated shape can also be determined to any shape such as a triangular shape, a square shape, an elliptical shape, etc., and is arranged in an arbitrary arrangement such as alternately arranging the above-mentioned annular arrangement further alternately or vertically and horizontally. Or irregularly. As the predetermined unit forming mold used in the present invention, for example, a forming mold having an arbitrary shape such as a mold that imitates a desired shape can be adopted. Furthermore,
The mixed pattern applied to the solidified formed article is formed by the above-mentioned predetermined unit forming type and the sending out of each liquid chocolate A, B (each viscous fluid) finally disposed to face the unit forming type. It can also be determined by setting the drop position of each of the liquid chocolates A and B (each viscous fluid) to be delivered in relation to the arrangement position of the holes. Furthermore, in the above-mentioned section nozzle 50, the section passage 53
May be branched and a part of the liquid chocolate C guided by the partition passage 53 may be sent out as a viscous fluid that forms a part of the mixed pattern.
In addition, the partition nozzle provided with the partition passage and the non-partition nozzle provided with the non-partition passage are not limited to the inverted truncated cone shape as described above, and may be set to any shape such as a rectangular shape. .

[0062]

[0063]

According to the first aspect of the present invention, there is provided a first mold sink.
The mechanism is configured such that the plurality of delivery holes provided in the non-compartment passage communicating with the plurality of delivery holes of the compartment passage are arranged to face the predetermined unit forming mold, so that the plurality of delivery holes merge in the non-compartment passage. was a marked effect such can be poured in a predetermined unit-forming at a predetermined state mixed enters each viscous fluid to an appropriate person. Therefore, this first mold sink mechanism is
The first solidified article of the present invention according to claim 6 which is used.
In the manufacturing method, a remarkable effect is obtained such that solidified articles formed by applying a predetermined mixed pattern that is appropriately blurred can be easily and accurately mass-produced.

A second mold sink according to the second aspect of the present invention.
In the middle of the non-partitioned passage, the perforated wall having at least one opening is provided so as to intersect with the fluid passage direction of the non-partitioned passage, so that each of the non-partitioned passages merges in the non-partitioned passage. This has a remarkable effect that the viscous fluid can be poured into a predetermined unit forming mold in a predetermined state where the viscous fluid is mixed in a desired degree. Therefore, this second
7. The second solid-state imaging device according to claim 6, wherein a mold sink mechanism is used.
In the method for producing a cured formed article, a remarkable effect is obtained such that a solidified formed article having a predetermined mixed pattern blurred to a desired degree can be easily and accurately mass-produced.

The third mold sink according to the third aspect of the present invention.
The structure is disposed in any combination of other delivery holes for delivering at least two kinds of viscous fluids so as to surround the at least one delivery hole on a predetermined surface facing the predetermined unit forming mold, By adopting a mode in which the viscous fluid is delivered based on the delivery timing set by the delivery timing setting and maintaining means, two or more kinds of viscous fluids are surrounded around at least one kind of viscous fluid covered and accommodated therein. This has a remarkable effect that it can be poured into a predetermined unit forming mold in a predetermined state. Therefore,
The present invention according to claim 7, wherein the third mold sink mechanism is used.
In the third method for producing a solidified formed article , a mass is easily and accurately mass-produced by forming at least one type of viscous fluid therein and applying a predetermined mixed pattern around the viscous fluid. The remarkable effect that it can be obtained is obtained.

A fourth mold sink according to the present invention according to claim 4.
The structure may include at least one non-partitioned passage provided in the non-partitioned passage communicating with the plurality of delivery holes of the divided passage arranged in any combination.
By adopting an aspect in which the two delivery holes are disposed so as to face the predetermined unit forming mold, two or more types of viscous fluids are merged around at least one type of viscous fluid covered and accommodated therein. This has a remarkable effect that it can be poured into a predetermined unit forming mold in a predetermined state that has been put together or in a predetermined state where it has been properly mixed. Therefore, this
The fourth aspect of the present invention according to the seventh aspect, wherein a fourth mold sink mechanism is used.
In the method for producing a solidified formed article of item 4, the solidified formed article is formed by coating and containing at least one kind of viscous fluid therein and applying a predetermined mixed pattern or a predetermined mixed pattern appropriately blurred therearound. A remarkable effect that mass production can be performed simply and accurately can be obtained.

A fifth mold sink according to the fifth aspect of the present invention.
In the structure , at least one type covered and accommodated inside is provided by adopting a mode in which a perforated wall having at least one opening is provided so as to intersect the fluid passage direction of the non-partitioned passage in the middle part of the non-partitioned passage. Around the viscous fluid, a remarkable effect that two or more kinds of viscous fluids can be poured into a predetermined unit forming mold in a predetermined state further mixed to a desired degree is produced. Therefore, this fifth type
The fifth solidification of the present invention according to claim 7, wherein a sink mechanism is used.
In a method of manufacturing a formed article, a solid formed article in which at least one kind of viscous fluid is coated and accommodated inside and a predetermined mixed pattern which is further blurred to a desired degree around the formed article is simply and accurately formed. A remarkable effect such as mass production can be obtained.

[Brief description of the drawings]

1A and 1B are exploded schematic perspective views showing an example of a mold casting mechanism of the present invention, and FIG. 1C is a schematic view showing an example of a unit forming mold for forming a single solidified formed article. It is a perspective view.

2A is a longitudinal sectional view taken along line 2a-2a in FIG. 1A, and FIG. 2B is a longitudinal sectional view taken along line 2b-2b in FIG. 1A.

FIGS. 3A and 3B are schematic perspective views showing another embodiment of the partition nozzle shown in FIG. 1A.

4 (a) to 4 (c) are schematic perspective views showing another embodiment of the non-partitioned nozzle shown in FIG. 1 (b).

5 (a) and 5 (b) are schematic exploded perspective views showing another embodiment of the mold casting mechanism of the present invention, and FIG. 5 (c) is another unit forming mold for forming a single solidified formed article. It is a schematic perspective view which shows an aspect.

6 (a) is a longitudinal sectional view taken along line 6a-6a in FIG. 5 (a), and FIG. 6 (b) is a longitudinal sectional view taken along line 6b-6b in FIG. 5 (a).

FIGS. 7A and 7B are schematic perspective views showing another embodiment of the partition nozzle shown in FIG. 5A.

8 (a) and 8 (b) are schematic perspective views showing another embodiment of the non-partitioned nozzle shown in FIG. 5 (b).

[Explanation of symbols]

 10,50 partition nozzle 11,12,51-53,82 partition passage 20,40,60,80 non-partition nozzle 21,41,61,81 non-partition passage 30,70 unit formation type 31,71 accommodation parts A-C Liquid chocolate (viscous fluid)

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁶ Identification code FI A23L 1/06 A23L 1/06

Claims (7)

(57) [Claims] 1. At least two kinds of viscosities having different color tones
A solidified article formed by applying a predetermined mixed pattern with a fluid
A mold casting mechanism used in the manufacture of a unit, and a predetermined unit forming mold for forming a single solidified formed article.
Then, a predetermined amount of each viscous fluid measured individually is individually
A plurality of compartment passages for guiding separately, each compartment passage
Each sending two or more types of viscous fluids provided at the same time
Holes are optional on the predetermined surface facing the unit forming mold
The combination is arranged, also with a non-compartment passage communicating with a plurality of delivery holes of the compartment passages arranged in any combination, a plurality of delivery holes formed above predetermined unit provided in the non-partitioned passage type flow mechanism you characterized in that it is disposed opposite to the mold. 2. At least two kinds of viscosities having different color tones
A solidified article formed by applying a predetermined mixed pattern with a fluid
A mold casting mechanism used in the manufacture of a unit, and a predetermined unit forming mold for forming a single solidified formed article.
Then, a predetermined amount of each viscous fluid measured individually is individually
A plurality of compartment passages for guiding separately, each compartment passage
Each sending two or more types of viscous fluids provided at the same time
Holes are optional on the predetermined surface facing the unit forming mold
In combination is arranged, also double the compartment passages arranged in any combination
A non-compartmental passage communicating with a number of delivery holes;
At least one delivery hole provided in the predetermined unit formation
Disposed opposite to the mold, in the middle portion of the non-compartmental passage, perforated wall having at least one opening is, you characterized in that provided to intersect the fluid passage direction of the non-compartment passage type Sink mechanism. 3. Viscosity of at least two kinds having different color tones
A solidified article formed by applying a predetermined mixed pattern with a fluid
A mold casting mechanism used in the manufacture of a unit, and a predetermined unit forming mold for forming a single solidified formed article.
Then, a predetermined amount of each viscous fluid measured individually is individually
A plurality of compartment passages for guiding separately, each compartment passage
Each sending two or more types of viscous fluids provided at the same time
Holes are optional on the predetermined surface facing the unit forming mold
The start of the delivery of the viscous fluid delivered from at least one delivery hole is delayed with respect to the delivery timing of the viscous fluid delivered from another delivery hole, and the delivery end of the delivery is delayed. further comprising a transmission timing setting maintaining means for setting so as to precede, in the predetermined plane facing the predetermined unit-forming, transmission timing by the means
So as to surround the delivery hole but is set, wherein said other respective delivery holes for delivering at least two viscous fluid is disposed in any combination type flow mechanism. 4. Viscosity of at least two kinds having different color tones
A solidified article formed by applying a predetermined mixed pattern with a fluid
A mold sink mechanism used in manufacturing Predefined unit forming mold for forming a single solidified formed article
Then, a predetermined amount of each viscous fluid measured individually is individually
A plurality of compartment passages for guiding separately, each compartment passage
Each sending two or more types of viscous fluids provided at the same time
Holes are optional on the predetermined surface facing the unit forming mold
Is arranged in combination with In addition, a plurality of the above-mentioned section passages arranged in any combination are provided.
A non-compartmental passage communicating with a number of delivery holes;
At least one delivery hole provided in the predetermined unit formation
It is arranged facing the mold, Delivery of viscous fluid delivered from at least one delivery hole
The timing is controlled by the delivery of viscous fluid delivered from other delivery holes.
Delay the start of transmission with respect to the output timing, and
Sending timing that sets the sending end of the data ahead
The apparatus further comprises a setting maintaining means, which faces the predetermined unit forming mold.
On the predetermined surface to be transmitted by the above means
At least so as to surround the delivery hole in which
The above-mentioned other delivery holes for delivering two kinds of viscous fluids are optionally provided.
A mold sink mechanism which is arranged in combination. 5. At least two kinds of viscosities having different color tones
A solidified article formed by applying a predetermined mixed pattern with a fluid
A mold sink mechanism used in manufacturing Predefined unit forming mold for forming a single solidified formed article
Then, a predetermined amount of each viscous fluid measured individually is individually
A plurality of compartment passages for guiding separately, each compartment passage
Each sending two or more types of viscous fluids provided at the same time
Holes are optional on the predetermined surface facing the unit forming mold
Is arranged in combination with In addition, a plurality of the above-mentioned section passages arranged in any combination are provided.
A non-compartmental passage communicating with a number of delivery holes;
At least one delivery hole provided in the predetermined unit formation
It is arranged facing the mold, In the middle of the non-compartmental passage, at least one open
A perforated wall having holes intersects the fluid passage direction of the non-compartmental passage.
Insert it, Delivery of viscous fluid delivered from at least one delivery hole
The timing is controlled by the delivery of viscous fluid delivered from other delivery holes.
Delay the start of transmission with respect to the output timing, and
Sending timing that sets the sending end of the data ahead
The apparatus further includes a setting maintaining means, and is opposed to the predetermined unit forming mold.
On the predetermined surface to be transmitted by the above means
At least so as to surround the delivery hole in which
The above-mentioned other delivery holes for delivering two kinds of viscous fluids are optionally provided.
A mold sink mechanism which is arranged in combination. 6. The mold casting mechanism according to claim 1 or 2.
Used, be by two or more of the viscous fluid A method for producing a solidified form article comprising performing a predetermined interwoven pattern, a step of weighing each viscous fluid individually predetermined quantity of metered individually in the process A step of guiding each viscous fluid through each passage provided in the mold casting mechanism according to claim 1 or 2, and sending the viscous fluid substantially simultaneously from a delivery hole arranged opposite to a predetermined unit forming mold. Receiving the viscous fluid sent out in the step in a predetermined unit forming mold and solidifying and forming the viscous fluid. 7. A method according to claim 3, wherein
A method of manufacturing a solidified formed article obtained by applying a predetermined mixed pattern with two or more types of viscous fluids using the mold flow mechanism of ( a), wherein each viscous fluid is individually measured; The mold sinker according to any one of claims 3 to 5 , wherein a predetermined amount of each viscous fluid is set.
Guiding through each of the passages provided in the frame, and sending out from a sending hole arranged opposite to a predetermined unit forming mold based on the sending timing set by the sending timing setting maintaining means; Receiving the sent viscous fluid in a predetermined unit forming mold and solidifying and forming the same.