JP2019132679A - Additive component quantitative supply device, and quantitative supply device of broth with additive component quantitative supply device - Google Patents

Abstract

To provide a quantitative supply device of broth that can supply a certain amount of the broth in a container at a uniform concentration and automatically so as to complement its flavor.SOLUTION: The device is constituted such that an additive component from a supply opening 54a open to a lower end of the additive component container 54 is dropped into a measuring hole portion 64 and is weighted by moving a weighing plate member 58 so that the measuring hole portion 64 is located in the addition component weighing supply unit 50, and the additive component weighed in the measuring hole portion 64 is supplied falling into a container 38 via a drop supply hole 66a formed in an additive component supply unit 52 by moving the weighting plate member 58 so that the measuring hole portion 64 is located in the additive component supply unit 52.SELECTED DRAWING: Figure 5

Description

  The present invention, for example, can automatically supply a certain amount of soup stock or miso soup, such as miso soup, udon, soba, ramen, and soup soup or dipping soaking noodles or dishes into the container at a uniform concentration. The present invention relates to a constant quantity supply device for soup stock that can be supplemented with flavor.

  In more detail, for such a soup stock, as a flavoring at the time of juice extraction, for example, there are cases where an additive component consisting of a powdered granule (powder or granule) such as bonito or kelp is added. An additive component quantitative supply device for automatically weighing such additive components and supplying the measured additive components into the container, and a soup stock quantitative supply device (so-called soup stock supply device provided with the additive component quantitative supply device) "Dispenser device").

  2. Description of the Related Art Conventionally, as a quantitative feeding device for such a soup, a soup stock quantitative feeding device as disclosed in Patent Document 1 (Japanese Patent No. 5435425) has been proposed. FIG. 22 is a schematic side view of the apparatus for supplying a constant amount of soup stock disclosed in Patent Document 1.

  As shown in FIG. 22, the fixed quantity supply device 100 for the soup stock of Patent Document 1 includes a fixed quantity supply device main body 102, and is composed of, for example, a paper pack or a resin container inside the fixed quantity supply device main body 102. A concentrating container 104 is arranged to be removable and replaceable.

  Note that the concentration container 104 is configured so that it can be easily replaced by removing the piping tube 114 when concentration does not occur.

  Further, the concentration container 104 may be configured such that, for example, a container with a cap commercially available for business use is used as it is, and the piping tube 114 is attached to the cap portion through the piping tube 114.

  Furthermore, a hot water tank 106 is provided inside the fixed quantity supply device main body 102, and hot water is supplied to the stock mixing unit 110 via the piping tube 112.

  Then, for example, by operating an operation button or an operation handle of a control device (not shown), the concentrated liquid from the concentrated container 104 is quantitatively supplied by the tube pump 108 to the soup stock mixing unit 110 via the piping tube 114. It has become so.

  In the soup stock mixing unit 110, the hot water supplied from the hot water tank 106 and the concentrated feed supplied in a constant amount from the concentrated discharge container 104 are mixed and placed on the mounting table 116, for example, miso soup cake, ramen Mixed soup is supplied into a container 120 such as a bowl.

  The hot water tank 106 is not shown in detail because of a conventionally known configuration, but a lower limit float for preventing emptying, an upper limit float for detecting that the hot water tank is full, and heating to a predetermined temperature. It has a heater and a temperature sensor for temperature measurement.

  Furthermore, a water supply pipe from the water supply can be attached, and this supply pipe is provided with a solenoid valve so that when the upper limit float operates, the solenoid valve is closed to stop the water supply. It is configured.

  Although not shown in the drawing, an exchangeable soup pack made of natural materials such as bonito and kelp is arranged inside the soup stock mixing unit 110, and the soup pack is squeezed out with hot water by a handle operation so that flavor such as aroma Is applied to the mixed soup stock.

  The soup stock mixed in this way is placed on a mounting table 116 arranged below the stock quantity dispensing device 100, for example, in a container 120 made of miso soup, udon, soba, bowl for ramen, etc. In addition, a predetermined amount is supplied.

  On the other hand, in Patent Document 2 (Japanese Patent No. 5105234), a drying tool material attached to a constant quantity supply device for a soup stock for supplying liquid food materials such as miso soup and sushi soup, and processed by a method such as freeze drying, for example. Ingredient supply devices have been proposed.

  FIG. 23 is a front view of the ingredient supply device of Patent Document 2, and FIG. 24 is an enlarged view of a portion I in FIG.

  As shown in FIG. 23, the ingredient supply device 210 of Patent Document 2 is a fixed-quantity supply device main body of a soup stock quantitative supply device 200 having the same configuration as that of the soup stock quantitative supply device 100 as disclosed in Patent Document 1. Attached to the side of 202.

  As shown in FIGS. 23 and 24, the ingredient supply device 210 includes an ingredient tank 204 that is attached to the side of the quantitative supply apparatus main body 202 and stores the ingredients.

  In addition, the ingredient 208 supplied from the ingredient tank 204 is placed on the placement table 206 of the stock quantity dispensing device 200, for example, a container 208 made of miso soup, udon, soba, bowl for ramen, and the like. A chute portion 222 is provided for moving inward.

  Further, as shown in FIG. 24, a screw member 212 that rotates by driving a motor (not shown) is provided below the material tank 204, and the material of the material tank 204 is rotated by the rotation of the screw member 212. As shown by arrows A and C in FIG. 24, the material falls on the chute portion 222.

  Further, a fan 218 is provided on the inlet side 214 of the chute portion 222 in order to reliably feed the ingredient B supplied from the ingredient tank 204 to the outlet side 216 of the chute portion 222.

  In addition, a filter 220 for separating the wind from the ingredient B is provided at the end of the outlet side 216 of the chute 222 by a plate having a net-like or slit-like gap.

  Thereby, the material B pushed out by the screw member 212 in the chute part 222 is freely dropped by gravity in the direction of arrow A by the air blown by the fan 218.

  Thereafter, the air generated by the fan 218 is carried in the chute 222 in the direction of arrow C. Then, the material B is dropped in the direction of arrow D by the filter 220 disposed at the end of the outlet side 216 of the chute portion 222.

  On the other hand, the wind is configured to pass through the filter 220 and escape to the outside of the chute portion 222. This prevents the wind from being blown into the container 208 and prevents the material B from being scattered.

  Further, in Patent Document 3 (Japanese Patent Laid-Open No. 2001-240068), for example, a lid is opened and closed inside a container for containing powdered or granular food T such as instant coffee, sugar, powdered milk, salt or the like. The conveyance apparatus which can set beforehand the quantity which takes out the foodstuff outside without requiring is disclosed.

  25 (A) to 25 (B) are partially enlarged cross-sectional views for explaining the outline of the operation of the transport apparatus 300 of Patent Document 3.

  As shown in FIG. 25A, the transport apparatus 300 includes a container main body 302 that stores the food T as described above. A slide weighing plate 306 slidable in the left-right direction is disposed on the bottom 304 of the container body 302.

  The slide measuring plate 306 is urged by a compression spring 308 in the direction in which the operation lever 310 protrudes.

  Further, the slide measuring plate 306 is formed with a measuring hole portion 312, and in the initial state of FIG. 25A, a position that matches the take-out hole 316 formed in the bottom wall 314 of the bottom portion 304 of the container body 302. It is comprised so that.

  Therefore, in this state, the food T accommodated in the container main body 302 falls into the measurement hole portion 312 formed in the slide measurement plate 306 through the take-out hole 316 formed in the bottom wall 314 of the container main body 302. It is like that.

  In this state, as shown in FIG. 25 (B), when the operation lever 310 is pushed against the compression spring 308, the measurement hole portion 312 formed in the slide measurement plate 306 becomes the bottom portion of the container main body 302. The state coincides with the discharge port 318 formed in 304. Thereby, the food T accommodated in the measurement hole 312 formed in the slide measurement plate 306 is measured and discharged.

Japanese Patent No. 5435425 Japanese Patent No. 5105234 JP 2001-240068 A

  By the way, there are cases where, for example, an additive component made up of powdered granules (powder or granules) such as bonito and kelp that impart a flavor may be added to the soup stock as a flavor during juice extraction.

  In this case, in the conventional stock dispenser 100 disclosed in Patent Document 1, an exchangeable soup pack made of a natural material such as bonito or kelp is disposed inside the stock mixing unit 110, and the handle The soup stock pack is squeezed out with hot water by operation, and a flavor such as aroma is imparted to the mixed soup stock.

  Therefore, in the fixed quantity supply device 100 of the soup stock disclosed in Patent Document 1, it is necessary to prepare the soup stock pack separately, which is costly and requires the stock soup pack used several times to be taken out from the stock stock mixing unit 110 and replaced. It takes time and effort.

  In addition, depending on the degree of squeezing the soup stock pack with hot water by operating the handle, the flavor changes and is not constant.

  Furthermore, in the fixed quantity supply apparatus 100 of the stock of patent document 1, the mixing ratio of flavor materials, such as aroma, cannot be changed arbitrarily, but in order to change the mixing ratio of flavor materials arbitrarily, another kind was different. A stock pack must be prepared and replaced, which is expensive and time consuming.

  In addition, in the material supply apparatus 210 of Patent Document 2, a screw member 212, a chute unit 222, a fan 218, a filter 220, and the like provided below the material tank 204 must be provided, which makes a complicated configuration and cost. It will be expensive.

  In addition, in the material supply apparatus 210 of this Patent Document 2, the mixing ratio of the material B cannot be changed, and the versatility is lacking.

  Furthermore, the conveying apparatus 300 of Patent Document 3 is intended for powdery or granular food T such as instant coffee, sugar, milk powder, salt, and the like, and is intended for the present invention. , Miso soup, udon, buckwheat noodles and other soup stocks, and soup soups and sauces in which noodles and dishes are soaked. It does not relate to the case of adding an additive component such as powder or granule.

  Moreover, in the conveyance apparatus 300 of patent document 3, the food T is what is called bridge | bridging in the corner part of the bottom wall 314 of the container main body 302 in the part enclosed by E part of FIG. 25 (A)-(B), for example. As a result, the takeout hole 316 formed in the bottom wall 314 of the bottom portion 304 of the container body 302 may become clogged, and the food T may not be taken out.

  In view of such a current situation, the present invention, for example, miso soup, udon, soba, ramen, etc., or soup or dipping soaking noodles or dishes, automatically and uniformly in a container. An object of the present invention is to provide an apparatus for supplying a constant amount of soup stock that can be supplied in a certain amount and supplemented with a flavor.

  In addition, the present invention automatically measures, for such a soup stock, an additive component consisting of a powdered granule (powder or granule) such as bonito or kelp that imparts a flavor as a flavoring during juice extraction. Then, it aims at providing the addition component fixed quantity supply apparatus which can supply the measured addition component in a container, and the fixed quantity supply apparatus of the soup stock provided with the addition component fixed quantity supply apparatus.

  Furthermore, the present invention provides an additive component quantitative supply device capable of arbitrarily changing the mixing type and mixing ratio of flavor materials such as aroma, and a stock juice quantitative supply device provided with the additive component quantitative supply device. With the goal.

The present invention was invented in order to achieve the above-described problems and objects in the prior art, and the additive component quantitative supply device of the present invention comprises:
An additive component quantitative supply device for measuring an additive component of a soup stock and supplying the measured additive component into a container,
A quantitative supply device main body for supplying the measured additive component into a container;
An additive component metering unit formed in the metering device body;
An additive component supply unit for supplying the additive component measured by the additive component measurement unit into the container;
An additive component storage container that is provided in the additive component metering unit and that stores the additive component to be weighed;
A metering plate member provided in the quantitative supply device body, provided so as to be movable between the additive component metering unit and the additive component feeding unit;
The measuring plate member is formed with a measuring hole for measuring an additive component falling from a supply opening opened at a lower end of the additive component storage container,
The metering plate member is moved so that the metering hole portion is positioned at the additive component metering supply portion, and the additive component is dropped into the metering hole portion from the supply opening portion opened at the lower end of the additive component container. Weighed,
Addition measured in the measurement hole through the drop supply hole formed in the additive component supply unit by moving the measurement plate member so that the measurement hole is positioned in the additive component supply unit The component is configured to be supplied by dropping into the container.

  By configuring in this way, the measuring plate member is moved so that the measuring hole portion is positioned at the additive component metering supply portion, and the additive component is measured from the supply opening that is opened at the lower end of the additive component storage container. Dropped into the unit and weighed.

  Then, by moving the measuring plate member so that the measuring hole portion is positioned in the additive component supply portion, the additive component measured in the measurement hole portion is passed through the drop supply hole formed in the additive component supply portion. It is configured to be dropped and supplied into the container.

  As a result, for example, a stock of miso soup, udon, soba, ramen, or a soup or dipping soaked in noodles or dishes can be automatically and uniformly supplied into the container in a certain amount. The flavor can be complemented and added.

  In addition, for such a soup stock, as an additional flavor during juice extraction, for example, the additive ingredients consisting of powdered granules (powder and granules) such as bonito and kelp that give the flavor are automatically weighed and weighed. The added additive component can be reliably supplied into the container.

  Moreover, since the bottom part (bottom wall) does not exist in an additive component storage container like conventional patent document 3, the additive ingredient measured in the measurement hole part is bridged and clogged without the additive ingredient bridging. It is possible to prevent the additive component from remaining in the additive component storage container while being surely dropped and supplied.

  Further, the additive component quantitative supply device of the present invention moves the measurement plate member so that the measurement hole portion is positioned in the additive component supply unit, thereby providing a drop supply hole formed in the additive component supply unit. And a vibration applying device for applying vibration when the additive component measured in the measuring hole is dropped and supplied into the container.

  By configuring in this way, the measuring plate member is moved so that the measuring hole portion is located in the additive component supply unit, and thus, into the measurement hole portion via the drop supply hole formed in the additive component supply unit. When the weighed additive component is dropped and supplied into the container, vibration is applied by the vibration applying device.

  As a result, the additive component weighed in the measuring hole is reliably dropped and supplied into the container, and the additive component is prevented from remaining in the additive component container without bridging the additive component and clogging. can do.

  In the additive component quantitative supply device according to the present invention, the vibration imparting device includes an elastic member provided in the quantitative supply device main body.

  By configuring in this way, for example, it is composed of elastic members such as anti-vibration rubber and compression coil springs. The added component is surely dropped and supplied into the container, and the additive component can be prevented from remaining in the additive component storage container.

  In the additive component quantitative supply device of the present invention, the vibration applying device includes a plate spring member provided in the quantitative supply device main body, and a contact portion provided on the measurement plate member side and contacting the plate spring member. It is comprised from these.

  With this configuration, when the measuring plate member is moved so that the measuring hole portion is positioned in the additive component supply unit, the plate spring member provided in the quantitative supply device main body and the measurement plate member side are provided. The contact portion comes into contact with each other, and moderately vibration is applied.

  As a result, the additive component weighed in the measuring hole is reliably dropped and supplied into the container, and the additive component is prevented from remaining in the additive component container without bridging the additive component and clogging. can do.

  In addition, the additive component quantitative supply device of the present invention is configured such that the vibration imparting device includes a recess provided in the quantitative supply device main body and a plunger member provided on the measurement plate member side and freely protruding and retracting in the recess. It is characterized by being.

  By comprising in this way, a vibration is provided moderately by the plunger member provided in the measurement plate member side appearing in the recessed part provided in the fixed quantity supply apparatus main body.

  As a result, the additive component weighed in the measuring hole is reliably dropped and supplied into the container, and the additive component is prevented from remaining in the additive component container without bridging the additive component and clogging. can do.

  The additive component quantitative supply device according to the present invention is characterized in that a fan that blows air downward toward the drop supply hole is provided above the drop supply hole formed in the additive component supply unit.

  By comprising in this way, ventilation is produced toward the downward direction of a fall supply hole with the fan provided above the fall supply hole formed in the additive component supply part.

  As a result, the additive component weighed in the measuring hole is surely dropped and supplied into the container without causing the additive component to bridge and clog due to the air blown from the fan, and the additive component is contained in the additive component storage container. It can be prevented from remaining.

  In addition, the steam from the soup in the container is blown from the fan to enter the drop supply hole formed in the additive component supply part and the measurement hole part of the measurement plate member, and the additive component is solidified. Can be prevented.

  Further, the additive component quantitative supply device of the present invention is characterized in that a plurality of measuring hole portions of the measuring plate member are formed corresponding to the types of the additive components.

  By comprising in this way, since the measurement hole part of a measurement board member is formed in multiple numbers corresponding to the kind of additive component, the mixing kind of flavor materials, such as fragrance, and a mixing ratio are changed arbitrarily. be able to.

  The additive component quantitative supply device according to the present invention is characterized in that each of the plurality of measurement hole portions has a volume determined according to a measurement value to be measured of each additive component. .

  By configuring in this way, a plurality of measuring hole portions are determined according to the measurement values to be measured of the respective additive components, so that the volume of each is determined. The mixing ratio can be further arbitrarily changed.

  Further, the additive component quantitative supply device of the present invention is characterized in that a plurality of the measuring plate members are formed corresponding to the kinds of additive components.

  By comprising in this way, according to the kind of additive component, by arbitrarily moving a plurality of measuring plate members formed, the mixing type and mixing ratio of flavor materials such as aroma can be further arbitrarily set. Can be changed.

  Moreover, the additive component quantitative supply device of the present invention is characterized in that the additive component storage container is configured to be detachable from the metering supply device main body.

  By configuring in this way, the additive component storage container is configured to be detachable from the quantitative supply device body, so the additive component storage container is removed from the quantitative supply device body, and the additive component storage container Maintenance, cleaning, etc. become easy.

  Moreover, the fixed quantity supply device of the soup stock of the present invention is characterized by including the additive component quantitative supply device described above.

  Moreover, the fixed quantity supply device for the soup stock according to the present invention is characterized in that the additive component quantitative supply device is configured to be detachable from the main body of the constant quantity supply device for the soup stock.

  By configuring in this way, it is easy to remove the additive component quantitative supply device from the stock quantity quantitative supply device body of the soup stock quantitative supply device, and to maintain and wash the additive component quantitative supply device and additive component storage container. It becomes.

  Further, in the stock supply quantitative supply device of the present invention, the quantitative supply device body of the additive component quantitative supply device is configured to be detachable with respect to the stock supply quantitative supply device body of the stock supply quantitative supply device. It is characterized by.

  By configuring in this way, the quantitative supply device body of the additive component quantitative supply device is removed from the stock supply quantitative supply device body of the soup stock quantitative supply device, and the maintenance of the quantitative supply device body, additive component storage container, Easy to clean.

  According to the present invention, the measuring plate member is moved so that the measuring hole portion is positioned at the additive component metering supply portion, and the additive component is fed into the measuring hole portion from the supply opening portion opened at the lower end of the additive component storage container. Dropped and weighed.

  Then, by moving the measuring plate member so that the measuring hole portion is positioned in the additive component supply portion, the additive component measured in the measurement hole portion is passed through the drop supply hole formed in the additive component supply portion. It is configured to be dropped and supplied into the container.

  As a result, for example, a stock of miso soup, udon, soba, ramen, or a soup or dipping soaked in noodles or dishes can be automatically and uniformly supplied into the container in a certain amount. The flavor can be complemented and added.

  In addition, for such a soup stock, as an additional flavor during juice extraction, for example, the additive ingredients consisting of powdered granules (powder and granules) such as bonito and kelp that give the flavor are automatically weighed and weighed. The added additive component can be reliably supplied into the container.

  Moreover, since the bottom part (bottom wall) does not exist in an additive component storage container like conventional patent document 3, the additive ingredient measured in the measurement hole part is bridged and clogged without the additive ingredient bridging. It is possible to prevent the additive component from remaining in the additive component storage container while being surely dropped and supplied.

FIG. 1 is a front view of a constant quantity supply device for a soup stock provided with an additive component quantitative supply device of the present invention. FIG. 2 is a side view in the A direction of the constant quantity supply device for the soup stock of FIG. FIG. 3 is a top view of the constant quantity supply device for the soup stock of FIG. FIG. 4 is an enlarged view for explaining the additive component quantitative supply device of FIG. 1. FIG. 5 is a side view in the A direction for explaining the additive component quantitative supply device of FIG. 4. FIG. 6 is a top view illustrating the additive component quantitative supply device of FIG. FIG. 7 is a partially enlarged view illustrating the additive component quantitative supply device of FIG. FIG. 8: is a partial front view of the state which closed the cover part of the fixed quantity supply apparatus of the soup stock provided with the additional component fixed quantity supply apparatus of another Example of this invention. FIG. 9: is a front view of the state which opened the cover part of the fixed quantity supply apparatus of the soup stock provided with the additional component fixed quantity supply apparatus of another Example of this invention. FIG. 10 is a side view in the A direction of the constant quantity supply device for the soup stock of FIG. FIG. 11 is a top view of the constant quantity supply device for the stock of FIG. FIG. 12 is an enlarged view for explaining the additive component quantitative supply device of FIG. 9. FIG. 13 is a side view in the A direction for explaining the additive component quantitative supply device of FIG. 12. FIG. 14 is a top view illustrating the additive component quantitative supply device of FIG. FIG. 15 is a partially enlarged view illustrating the additive component quantitative supply device of FIG. FIG. 16 is a partially enlarged view illustrating an additive component quantitative supply device according to another embodiment of the present invention. FIG. 17 is an enlarged view for explaining an additive component quantitative supply device according to another embodiment of the present invention. FIG. 18 is a side view in the A direction for explaining the additive component quantitative supply device of FIG. 17. FIG. 19 is a top view illustrating the additive component quantitative supply device of FIG. FIG. 20 shows the addition component quantitative supply device of FIG. 17, in order to facilitate maintenance, the constant supply device main body 48 and the additive component storage containers 51 a and 51 b are arranged on the supply device main body 12 side of the stock feed quantitative supply device 10. FIG. 5 is a side view illustrating a configuration that is detachable with the drive motor 78, the fan 70, and the position sensor 71 remaining. FIG. 21 is a top view of FIG. FIG. 22 is a side view of the constant quantity supply device 100 for the soup stock of Patent Document 1. FIG. 23 is a front view of the ingredient supply device 210 of Patent Document 2. FIG. 24 is an enlarged view of a portion I in FIG. 23 of the ingredient supply device 210 of Patent Document 2. 25 (A) to 25 (B) are partially enlarged cross-sectional views for explaining the outline of the operation of the transport apparatus 300 of Patent Document 3.

Hereinafter, embodiments (examples) of the present invention will be described in more detail with reference to the drawings.
Example 1

  FIG. 1 is a front view of a constant quantity supply device for a soup stock provided with an additive component quantitative supply device of the present invention, FIG. 2 is a side view in the direction A of the constant quantity supply device for the soup stock of FIG. 1, and FIG. FIG. 4 is an enlarged view for explaining the additive component quantitative supply device of FIG. 1, FIG. 5 is a side view in the A direction for explaining the additive component quantitative supply device of FIG. 4, and FIG. FIG. 7 is a top view for explaining the additive component quantitative supply device of FIG. 4, and FIG. 7 is a partially enlarged view for explaining the additive component quantitative supply device of FIG.

  1-6, the code | symbol 10 has shown the fixed_quantity | quantitative_feed apparatus of the soup stock provided with the additive component fixed_quantity | feed_rate supply apparatus of this invention as a whole.

  As shown in FIG. 1 to FIG. 4, the fixed quantity supply device 10 for the soup stock is provided with a supply device main body 12. A first concentrating container 14a made up of a bottle) (in this example, a plastic bottle is illustrated) is detachably and replaceably disposed.

  Note that the first concentrating container 14a is configured so that it can be easily replaced by removing the piping tube 16a when the concentrating out is stopped.

  Moreover, the 1st concentration container 14a may be comprised so that the piping tube 16a may be attached through the piping tube 16a to a cap part, for example using the container with a cap marketed for business as it is. .

  Then, by operating the operation button 26 of the control unit 24, the concentrated extract from the first concentrated discharge container 14a is quantitatively supplied to the soup stock mixing unit 30 by the first tube pump 28a via the piping tube 30a. It has become so.

  Similarly, the supply device main body 12 includes a second pack made of, for example, a paper pack for soup Y or a resin container (pet bottle) (in this embodiment, a plastic bottle is illustrated). The concentration container 14b is disposed so as to be removable and replaceable.

  Note that the second concentrating container 14b is configured so that it can be easily replaced by removing the piping tube 16b when the concentrating is stopped.

  The second concentration container 14b may be configured such that, for example, a commercially available container with a cap is used as it is, and the piping tube 16b is attached to the cap portion through the piping tube 16b. .

  Then, by operating the operation button 26 of the control unit 24, the concentrated extract from the second concentrated discharge container 14b is quantitatively supplied to the soup stock mixing unit 30 by the second tube pump 28b via the piping tube 30b. It has become so.

  In this embodiment, by operating the operation button 26 of the control unit 24, the soup X from the first concentrating container 14a for the soup X and the soup from the second concentrating container 14b for the soup Y Y is selectively supplied to the stock mixing unit 30 selectively.

  In this case, in this embodiment, there are two types of concentration and extraction containers 14, a first concentration and extraction container 14 a for the soup X and a second concentration and extraction container 14 b for the soup Y, but one type of concentration The discharge container 14 may be disposed, or three or more types of concentrated discharge containers 14 may be disposed.

  Further, by operating the operation button 26 under the control of the control unit 24, the operation time and the delivery amount of the tube pump 28 (the first tube pump 28a and the second tube pump 28b) are changed, and two or more types are changed. You may make it mix soup stock.

  On the other hand, as shown in FIG. 2, a hot water tank 32 is provided in the supply device main body 12 on the rear side thereof, and a certain amount is supplied to the soup stock mixing unit 30 via a pipe tube and a solenoid valve (not shown). Hot water is supplied.

  Then, in the soup stock mixing unit 30, the hot water supplied from the hot water tank 32 and the concentrated stock supplied from the concentrated stock container 14 (the stock X from the first concentrated stock container 14a for the stock X or the stock Y Soup Y) from the second concentrated discharge container 14b.

  As a result, the mixed soup is supplied into a container 38 such as miso soup koji or ramen bowl placed on the mounting table 34 through the nozzle 36 of the soup stock mixing unit 30. Yes.

  The hot water tank 32 is not shown in detail because of a conventionally known configuration, but a lower limit float for preventing emptying, an upper limit float for detecting that the hot water tank 32 is full, and a predetermined temperature. It is equipped with a heater for heating and a temperature sensor for temperature measurement.

  Furthermore, a water supply pipe from the water supply can be attached, and this supply pipe is provided with a solenoid valve so that when the upper limit float operates, the solenoid valve is closed to stop the water supply. It is configured.

  By the way, as an additional seasoning for the soup stock, for example, an additive component consisting of powdered granules (powder and granules) such as bonito and kelp that impart flavor (hereinafter simply referred to as “additive component”) May be included.

  For this reason, in the fixed quantity supply device 10 of the soup stock of the present invention, as shown in FIGS. 1 to 6, the additive component of the soup stock is measured on one side portion 12a of the supply device main body 12, and the measured addition An additive component quantitative supply device 40 for supplying the components into the container 38 is attached.

  That is, as shown in FIGS. 1 to 6, the additive component quantitative supply device 40 is connected to the supply device main body 12 of the soup quantitative supply device 10 by the mounting bolt 45 (see FIG. 5) via the mounting bracket 42. It is attached to one side 12a.

  The additive component quantitative supply device 40 is provided with an elastic member 43 such as an anti-vibration rubber or a compression coil spring, which functions as a vibration applying device, which will be described later, inserted into the mounting bolt 41.

  A main body side bracket 46 is attached to the attachment bracket 42 via an attachment bolt 41 and an elastic member 43.

  As shown in FIGS. 4 to 6, the main body side bracket 46 is attached with a quantitative supply device main body 48 that supplies additive components measured as described later into the container 38.

  The metering supply device main body 48 has an additive component metering supply unit 50 formed on the front side, and an additive for feeding the additive component weighed by the additive component metering supply unit 50 into the container 38 on the rear side. A component supply unit 52 is formed.

  The additive component metering supply section 50 is provided with a substantially cylindrical additive component storage container 54 that stores the additive component to be weighed therein.

  A detachable lid member 56 is attached to the upper end of the additive component storage container 54, and the additive component can be replenished by removing the lid member 56.

  That is, the additive component metering supply unit 50 is provided with a supply hole 50a that opens in the vertical direction, and the additive component storage container 54 is mounted on the supply hole 50a.

  In addition, a metering plate member 58 that is slidable in the front-rear direction is provided inside the quantitative supply device main body 48. As shown in FIG. 5, an operation handle 55 that is bent in a substantially L shape in the vertical direction is extended to the front end portion of the measuring plate member 58.

  The operation handle 55 is provided with a substantially circular push button portion 57 on the outer side in order to make it easier to push the operation handle 55 backward with a finger or the like.

  A drive mechanism 60 is formed on the lower side of the quantitative supply device main body 48, and a guide rod member 65 movable in the front-rear direction is mounted inside the drive mechanism 60. The front end of the guide bar member 65 is connected to the operation handle 55.

  Further, a coil spring 62 is interposed in the guide rod member 65 in a compressed state, and the operation handle 55, that is, the measuring plate member 58 is always urged forward by the urging force of the coil spring 62. It has become.

  As shown in FIGS. 5 to 7, the measurement plate member 58 is formed with a measurement hole portion 64 that opens up and down and has a volume corresponding to a predetermined measurement volume of the additive component.

  On the other hand, the additive component supply unit 52 of the quantitative supply device main body 48 has a drop recess 66, and a drop supply hole 66 a having a smaller diameter than the drop recess 66 opening up and down is formed in the drop recess 66.

  Further, a fan 70 is provided above the drop recess 66 of the additive component supply unit 52 of the quantitative supply device main body 48 to blow air toward the lower side of the drop supply hole 66a.

  A chute member 68 is formed so as to communicate with the drop supply hole 66a of the additive component supply unit 52 of the quantitative supply device main body 48. As shown in FIG. 4, a nozzle 68 a is formed at the tip of the chute member 68.

  And this nozzle 68a is arrange | positioned by the support bracket 73 of a substantially L shape so that the nozzle 36 of the stock mixing part 30 of the supply apparatus main body 12 of the stock supply constant quantity device 10 may adjoin.

  Further, a plate spring member 72 protruding forward is formed at the lower end of the drive mechanism portion 60 of the quantitative supply device main body 48 and functions as a vibration applying device for applying vibration. The leaf spring member 72 is formed with a bent projecting portion 72a that functions as a vibration applying device that applies vibration and is bent so as to project upward.

  In this case, as shown in FIG. 5, the lower end portion of the operation handle 55 constitutes an abutting portion 59 that abuts on the bent projecting portion 72 a of the leaf spring member 72.

  Further, the fan 70 can open and close the drop recess 66 of the additive component supply unit 52 of the quantitative supply device main body 48 for maintenance as shown by the arrow in FIG. 5 by the hinge member 74. ing.

  As shown in FIGS. 5 and 7, the additive component quantitative supply device 40 of the present invention configured as described above is operated as follows.

  First, in the initial state, the operation handle 55 of the measuring plate member 58, that is, the measuring plate member 58 is urged forward by the urging force of the coil spring 62 interposed in the compressed state of the guide bar member 65. (See solid line positions in FIGS. 5 and 7).

  In this state, the measurement hole 64 of the measurement plate member 58 is located in the additive component measurement supply unit 50. Then, the additive component is dropped into the measurement hole portion 64 of the measurement plate member 58 from the supply opening 54a opened at the lower end of the additive component storage container 54, and is measured.

  Next, from this state, the operation handle 55 is pushed backward with the finger or the like via the push button portion 57.

  As a result, the measuring plate member 58 is positioned in the drop recess 66 of the additive component supplying unit 52 against the urging force of the coil spring 62 interposed in the compressed state of the guide bar member 65. To be moved.

  In this state, the measurement hole 64 of the measurement plate member 58 is positioned above the drop supply hole 66a of the drop recess 66 of the additive component supply unit 52 (see the position of the dashed line in FIGS. 5 and 7).

  As a result, the additive component weighed into the measurement hole portion 64 of the measurement plate member 58 passes through the drop supply hole 66a of the drop recess 66 of the additive component supply portion 52, drops the chute member 68, and the chute member 68. It is configured to be dropped and supplied into the container 38 through the nozzle 68a at the tip of the container.

  With this configuration, the measuring plate member 58 is moved so that the measuring hole 64 is positioned in the additive component metering supply unit 50 and added from the supply opening 54a opened at the lower end of the additive component container 54. Ingredients are dropped into the metering hole 64 and weighed.

  Then, the measurement plate member 58 is moved so that the measurement hole 64 is positioned in the additive component supply unit 52, so that the measurement plate member 58 enters the measurement hole portion 64 via the drop supply hole 66 a formed in the additive component supply unit 52. The weighed additive component is configured to be dropped and supplied into the container 38.

  As a result, for example, a certain amount of miso soup, udon, soba, ramen, etc., or a soup or dipping soaked in noodles or dishes can be automatically and uniformly supplied into the container 38. , It can be added to complement the flavor.

  In addition, for such a soup stock, as an additional flavor during juice extraction, for example, the additive ingredients consisting of powdered granules (powder and granules) such as bonito and kelp that give the flavor are automatically weighed and weighed. The added additive component can be reliably supplied into the container 38.

  Further, as in the conventional Patent Document 3, since the additive component container 54 does not have a bottom (bottom wall), the additive component does not bridge and become clogged, so that the additive component container 54 does not clog in the measurement hole portion 64 of the measurement plate member 58. The weighed additive component is surely dropped and supplied into the container 38, and the additive component can be prevented from remaining in the additive component storage container 54.

  Further, since the vibration applying device is composed of an elastic member 43 such as an anti-vibration rubber and a compression coil spring, for example, the vibration is appropriately applied and the additive component bridges and is not clogged. The additive component weighed in the measurement hole 64 is surely dropped and supplied into the container 38, and the additive component can be prevented from remaining in the additive component storage container 54.

  That is, when the measuring plate member 58 is moved so that the measuring hole portion 64 is positioned in the additive component supply unit 52, the additive component that has been subjected to vibration and measured in the measuring hole portion 64 of the measuring plate member 58 is measured. However, it is surely dropped and supplied into the container 38.

  Further, when the metering plate member 58 is moved so that the metering hole 64 is positioned in the additive component supply unit 52, the plate spring member 72 (bending protrusion) provided in the drive mechanism unit 60 of the quantitative supply device body 48 is used. The portion 72a) comes into contact with the contact portion 59 provided on the measuring plate member 58 side (that is, when the contact portion 59 gets over the bent projecting portion 72a), and appropriate vibration is applied.

  As a result, the additive component weighed in the measuring hole 64 is reliably dropped and supplied into the container 38 without causing the additive component to bridge and clog, and the additive component remains in the additive component storage container 54. Can be prevented.

  Further, since the fan 70 for blowing air toward the lower side of the drop supply hole 66a is provided above the drop recess 66 of the additive component supply unit 52 of the quantitative supply device body 48, the fan 70 causes the drop supply hole 66a to Blowing occurs downward.

  As a result, the additive component weighed in the measuring hole 64 is surely dropped and supplied into the container 38 without causing the additive component to bridge and become clogged by the blowing from the fan 70, and the additive component storage container 54. It is possible to prevent the additive component from remaining inside.

  Further, the steam that has risen from the stock in the container 38 by blowing from the fan 70 enters the chute member 68, the drop supply hole 66 a formed in the additive component supply part 52, and the measurement hole part 64 of the measurement plate member 58. Thus, the additive component can be prevented from solidifying.

  In this embodiment, it is configured to manually push in the backward direction via the push button 57 of the operation handle 55 with a finger or the like. However, it is automatically driven by a drive mechanism such as a solenoid. It is also possible to do so.

  Furthermore, in this embodiment, the quantitative supply device main body 48 has an additive component metering supply unit 50 formed on the front side, and the additive component measured by the additive component metering supply unit 50 on the rear side. An additive component supply unit 52 for supplying the inside is formed.

  However, in the reverse arrangement, that is, the additive component metering supply unit 50 is formed on the rear side, and the additive component measured by the additive component metering supply unit 50 is supplied to the container 38 on the front side. The additive component supply unit 52 may be formed (the same applies to the following embodiments).

Further, in this embodiment, the additive component storage container 54, the measurement hole portion 64 of the measurement plate member 58, and the drop supply hole 66a formed in the additive component supply portion 52 are single, but a plurality of these are provided. It is also possible to provide it.
(Example 2)

  FIG. 8 is a partial front view showing a state in which the lid portion of a constant quantity supply device for stock with an additive component quantitative supply device according to another embodiment of the present invention is closed, and FIG. 9 is an addition according to another embodiment of the present invention. FIG. 10 is a side view in the direction A of the constant quantity supply device for the soup stock of FIG. 9, and FIG. 11 is the soup stock of FIG. 12 is an enlarged view for explaining the additive component quantitative supply device of FIG. 9, FIG. 13 is a side view in the direction A for explaining the additive component quantitative supply device of FIG. 12, and FIG. 12 is a top view for explaining the additive component quantitative supply device of FIG. 12, FIG. 15 is a partially enlarged view for explaining the additive component quantitative supply device of FIG. 12, and FIG. 16 is an additive component quantitative supply of another embodiment of the present invention. It is the elements on larger scale explaining an apparatus.

  The fixed quantity supply device 10 of this embodiment has basically the same configuration as the fixed quantity supply device 10 shown in FIGS. 1 to 7, and the same reference numerals are assigned to the same components. Detailed description thereof will be omitted.

  In the soup stock quantitative supply device 10 of this embodiment, as shown in FIGS. 8 to 15, the additive component quantitative supply device 40 is directly connected to one side portion of the supply device main body 12 via the main body side bracket 46. It is attached to 12a.

  Moreover, as shown in FIG. 10, the cover part 13 is comprised so that opening and closing is possible centering | focusing on the rotation part 11 comprised from a pivot axis | shaft. As will be described later, the lid 13 is provided with a control unit 15 provided with buttons for selecting the additive component P and additive component Q and a button 26 for driving the additive component quantitative supply device 40. .

  Further, as shown in FIGS. 13 to 14, the quantitative supply device main body 48 of this embodiment has an additive component metering supply section 50 formed on the rear side and the front side thereof, contrary to the first embodiment. In addition, an additive component supply unit 52 for supplying the additive component measured by the additive component metering supply unit 50 into the container 38 is formed.

  In addition, in order to measure a plurality of (two types in this embodiment) additive component P and additive component Q, the additive component metering unit 50 includes a plurality of (two in this embodiment) additive components. A storage container 51a and an additive component storage container 51b are provided.

  Corresponding to this, as shown in FIG. 14, a plurality of (two in this embodiment) supply hole portions 53a and 53b that open in the vertical direction are formed, and the supply hole portions 53a and 53b An additive component storage container 51a and an additive component storage container 51b are mounted on the upper part, respectively.

  Further, as shown in FIG. 14, the measuring plate member 58 has a measuring hole 64a and a measuring hole 64b having a volume corresponding to a predetermined measuring volume of the additive component. Yes.

  Furthermore, as shown in FIG. 14, the additive component supply unit 52 of the quantitative supply device main body 48 has a plurality of (two in this embodiment) drop recesses 61a and 61b, and the drop recesses 61a and 61b. In addition, drop supply holes 63a and 63b having a diameter smaller than that of the drop recesses 61a and 61b that open upward and downward are formed.

  Further, as shown in FIG. 12, these drop supply holes 63 a and 63 b merge at the funnel portion 67 so that the added additive component P and additive component Q are dropped onto the chute member 68. ing.

  Furthermore, as shown in FIGS. 13 to 15, a drive mechanism 75 is provided on the rear side of the fixed amount supply device main body 48.

  As shown in FIGS. 14 and 15, the drive mechanism 75 includes a guide member 76 provided on the rear end side of the measuring plate member 58. The guide member 76 includes two parallel guide portions 76a that are spaced apart from each other by a predetermined distance in the width direction, and a guide groove 76c that is formed between the parallel guide portions 76a.

  A drive motor 78 is attached above the guide member 76, and a substantially L-shaped drive ring 80 is fixed to the drive shaft 77 below the guide member 76 in plan view.

  The drive ring 80 includes a guide projecting portion 82 that slides in the guide groove 76c of the guide member 76 at the tip of the first link member 80a. In addition, a plunger member 84 that can move up and down in the vertical direction is provided at the tip of the second link member 80b.

  The fixed amount supply device main body 48 is provided with a mounting plate 86 for the drive motor 78, and the mounting plate 86 is formed with a recess (or hole) 86a for the tip of the plunger member 84 to appear and disappear. ing.

  With this configuration, the drive shaft 77 is rotated by the drive of the drive motor 78, so that the guide projecting portion 82 of the first link member 80 a slides in the guide groove 76 c of the guide member 76. .

As a result, the rotational motion is changed to a linear motion, and the measurement hole 64a and the measurement hole 64b of the measurement plate member 58 are positioned in the additive component measurement supply unit 50, and the measurement hole 64a of the measurement plate member 58. The measurement hole 64b can be moved by driving the drive motor 78 in the forward and reverse directions between the drop recesses 61a and 61b of the additive component supply unit 52 and the drop supply holes 63a and 63b. It is like that.
In this case, instead of driving the drive motor 78 in the forward and reverse directions, the drive motor 78 may be driven to rotate in one direction.

  The rotation stop position of the drive motor 78 may be determined by a position sensor 71 such as a photomicro sensor or a proximity sensor.

  Further, the vibration of the plunger member 84 provided on the measuring plate member 58 side appears and disappears in the recess 86a provided on the mounting plate 86 of the drive motor 78 of the quantitative supply device main body 48, so that moderate vibration is imparted. The

  As a result, the additive component weighed in the measuring hole is reliably dropped and supplied into the container, and the additive component is prevented from remaining in the additive component container without bridging the additive component and clogging. can do.

  In this embodiment, the additive component P and additive component Q are mixed in such a manner that the hole diameter of the measuring component 64a for the additive component P is different from the hole diameter for the additive component Q. Can be changed.

For example, when there is a container 38 of two sizes large and small as the container 38 (when the blending ratio is the same),
For small size: additive component P is 0.2 g, additive component Q is 0.4 g
For large size: additive component P is 0.3 g, additive component Q is 0.6 g
given that,
As the measuring component 64a for the additive component P, for example, a hole corresponding to 0.1 g is formed, and as the measuring component 64b for the additive component Q, for example, formed as a hole corresponding to 0.2 g, the small size In the case of, we can measure by measuring twice, and in the case of a large size, we can measure by measuring three times.

  In this case, the volume of the measuring component 64a for the additive component P and the volume of the measuring component 64b for the additive component Q can be changed, and it is of course possible to perform the measurement by one measurement.

  Moreover, what is necessary is just as follows when changing the mixture ratio of the addition component P and the addition component Q previously.

  For example, as shown in FIG. 16, the first weighing plate member 58a having the measurement hole 64a for the additive component P and the second measurement plate member 58b having the measurement hole 64b for the addition component Q are separated. While setting it as the measurement board member 58, let the volume of the hole of the measurement hole part 64a for these addition components P and the measurement hole part 64b for the addition component Q be the same volume. (For example, it is formed as a hole corresponding to 0.1 g)

  Then, the first measuring plate member 58a and the second measuring plate member 58b are separately driven by the first driving motor 78a and the second driving motor 78b, respectively, and the first measuring plate member 58a, The second weighing plate member 58b may be driven separately.

  For example, when the additive component P is 0.2 g and the additive component Q is 0.4 g, the first measuring plate member 58a is moved twice to measure twice, and the second measuring plate member 58b is set to 4 Move four times and measure four times.

  By comprising in this way, since the measurement hole part 64 of the measurement board member 58 is formed in multiple numbers corresponding to the kind of addition component, the mixing kind of flavor materials, such as fragrance, and a mixing ratio are made arbitrarily. Can be changed.

  In addition, since the plurality of measuring hole portions 64 are determined according to the measurement values of the respective additive components to be measured, the mixing type and mixing ratio of flavor materials such as fragrances, Furthermore, it can change arbitrarily.

Furthermore, the mixing type and mixing ratio of flavor materials such as aroma can be further arbitrarily changed by arbitrarily moving a plurality of formed measuring plate members in accordance with the types of additive components.
Example 3

  FIG. 17 is an enlarged view for explaining an additive component quantitative supply device according to another embodiment of the present invention, FIG. 18 is a side view in the A direction for explaining the additive component quantitative supply device of FIG. 17, and FIG. FIG. 20 is a top view for explaining the additive component quantitative supply device, FIG. 20 is an additive component quantitative supply device in FIG. FIG. 21 is a top view of FIG. 20, and FIG. 21 is a side view illustrating a detachable configuration with the drive motor 78, the fan 70, and the position sensor 71 remaining on the supply device body 12 side of the supply device 10.

  The fixed quantity supply device 10 of this embodiment has basically the same configuration as the fixed quantity supply device 10 shown in FIGS. 8 to 16, and the same reference numerals are assigned to the same components. Detailed description thereof will be omitted.

  As shown in FIGS. 17 to 21, in the stock feed quantitative supply device 10, the additive component quantitative supply device 40 is provided with a fixed supply device main body 48 and additive component accommodation by an attachment screw 88 in order to facilitate maintenance. The containers 51a and 51b are configured to be detachable with the drive motor 78, the fan 70, and the position sensor 71 remaining on the supply device main body 12 side of the stock supply quantitative supply device 10 (FIGS. 20 to 21). See arrow).

  Furthermore, as shown in FIG. 20, the additive component storage containers 51 a and 51 b are configured to be detachable with respect to the quantitative supply device main body 48.

  With this configuration, the additive component storage containers 51a and 51b are configured to be detachable from the quantitative supply device main body 48. Therefore, the additive component storage containers 51a and 51b can be removed from the quantitative supply device main body 48. By removing, the maintenance and cleaning of the additive component container are facilitated.

  In addition, the additive component quantitative supply device 40 is removed from the soup quantitative feed device main body 12 of the soup stock quantitative supply device 10 so that maintenance, washing, etc. of the additive component quantitative supply device 40 and the additive component storage container 54 are facilitated. Become.

  Further, the quantitative supply device main body 44 of the additive component quantitative supply device 40 is detached from the soup quantitative feed device main body 12 of the soup stock quantitative supply device 10, and the quantitative feed device main body 12 and the additive component storage containers 51a, 51b are removed. Maintenance, cleaning, etc. become easy.

As shown in FIG. 18 to FIG. 19, the quantitative supply device main body 48 is the quantitative supply device main body before removing the components such as the additive component storage containers 51 a and 51 b, the drive motor 78, the fan 70, and the position sensor 71. Shows the whole.
Also, as shown in FIGS. 20 to 21, the quantitative supply device main body 44 is a fixed-quantity supply device with the additional component storage containers 51 a and 51 b, the drive motor 78, the fan 70, the position sensor 71, etc. removed. Shows the body.

  As mentioned above, although the Example of this invention was described, this invention is not limited to the said Example, For example, in the said Example, as additive ingredients, for example, flour, such as bonito and kelp which gives flavor Although an additive component made of granules (powder or granule) is used, although not shown, it is also possible to use an additive component such as a liquid or a viscous liquid by imparting a sealing property.

  Furthermore, the supply timing of the additive component by the additive component quantitative supply device 40 can be arbitrarily set, for example, before the soup extraction, after the soup extraction, or simultaneously with the extraction of the soup. It can be changed.

  The present invention, for example, can automatically supply a certain amount of soup stock or miso soup, such as miso soup, udon, soba, ramen, and soup soup or dipping soaking noodles or dishes into the container at a uniform concentration. In addition, the present invention can be applied to a constant quantity supply device for soup stock that can be supplemented with flavor.

  In more detail, for such a soup stock, as a flavoring at the time of juice extraction, for example, there are cases where an additive component consisting of a powdered granule (powder or granule) such as bonito or kelp is added. , Automatically metering such additive components, and applying to the additive component quantitative supply device for supplying the metered additive component into the container, and the constant quantity supply device for stock with the additive component quantitative supply device can do.

DESCRIPTION OF SYMBOLS 10 Constant supply apparatus 11 Rotating part 12 Supply apparatus main body 12 Fixed supply apparatus main body 12a Side part 13 Lid part 14 Concentration container 14a 1st concentrating container 14b 2nd concentrating container 15 Control part 16a Piping tube 16b Piping tube 24 control unit 26 operation button 28 tube pump 28a first tube pump 28b second tube pump 30 stock mixing unit 30a piping tube 30b piping tube 32 hot water tank 34 mounting table 36 nozzle 38 container 40 additive component quantitative supply devices 41, 45 Mounting bolt 42 Mounting bracket 43 Elastic member 44 Fixed amount supply device main body 46 Main body side bracket 48 Fixed amount supply device main body 50 Additive component metering supply portion 50a Supply hole portion 51a, 51b Additive component storage container 52 Additive component supply portion 53a, 53b Supply hole portion 54 Additive component capacity Container 54a Supply opening 55 Operation handle 56 Lid member 57 Press button portion 58 Measuring plate member 58a First measuring plate member 58b Second measuring plate member 59 Contact portion 60 Drive mechanism portions 61a and 61b Drop recess 62 Coil spring 63a 63b Drop supply hole 64 Metering hole 64a, 64b Metering hole 65 Guide rod member 67 Roto part 66 Drop recess 66a Drop supply hole 68 Chute member 68a Nozzle 70 Fan 71 Position sensor 72 Leaf spring member 72a Bending protrusion 73 Support bracket 74 Hinge member 75 Drive mechanism 76 Guide member 76a Parallel guide portion 76c Guide groove 77 Drive shaft 78 Drive motor 78a First drive motor 78b Second drive motor 80 Drive ring 80a First link member 80b Second link Member 82 Guide protrusion 84 Plunger member 86 Retaining plate 86a Recess (or hole)
88 Mounting screw 100 Fixed amount supply device 102 Fixed amount supply device main body 104 Concentrated supply container 106 Hot water tank 108 Tube pump 110 Dipping juice mixing part 112 Pipe tube 114 Pipe tube 116 Mounting table 120 Container 200 Fixed amount supply device 202 Fixed amount supply device main body 204 Material tank 206 Loading table 208 Container 210 Material supply device 212 Screw member 214 Inlet side 216 Outlet side 218 Fan 220 Filter 222 Chute unit 300 Conveying device 302 Container body 304 Bottom portion 306 Slide measuring plate 308 Compression spring 310 Operation lever 312 Measuring hole 314 Bottom wall 316 Removal hole 318 Discharge port A Arrow B Ingredient C Arrow D Arrow T Food P Additive ingredient Q Additive ingredient X, Y

Claims (13)

An additive component quantitative supply device for measuring an additive component of a soup stock and supplying the measured additive component into a container,
A quantitative supply device main body for supplying the measured additive component into a container;
An additive component metering unit formed in the metering device body;
An additive component supply unit for supplying the additive component measured by the additive component measurement unit into the container;
An additive component storage container that is provided in the additive component metering unit and that stores the additive component to be weighed;
A metering plate member provided in the quantitative supply device body, provided so as to be movable between the additive component metering unit and the additive component feeding unit;
The measuring plate member is formed with a measuring hole for measuring an additive component falling from a supply opening opened at a lower end of the additive component storage container,
The metering plate member is moved so that the metering hole portion is positioned at the additive component metering supply portion, and the additive component is dropped into the metering hole portion from the supply opening portion opened at the lower end of the additive component container. Weighed,
Addition measured in the measurement hole through the drop supply hole formed in the additive component supply unit by moving the measurement plate member so that the measurement hole is positioned in the additive component supply unit An additive component quantitative supply device, wherein the component is configured to be supplied by dropping into the container.   Addition measured in the measurement hole through the drop supply hole formed in the additive component supply unit by moving the measurement plate member so that the measurement hole is positioned in the additive component supply unit 2. The additive component quantitative supply device according to claim 1, further comprising a vibration applying device that applies vibration when the component is dropped and supplied into the container.   3. The additive component quantitative supply device according to claim 2, wherein the vibration applying device is constituted by an elastic member provided in the quantitative supply device main body.   The vibration applying device includes a leaf spring member provided in the quantitative supply device main body, and a contact portion provided on the measuring plate member side and in contact with the leaf spring member. The additive component quantitative supply device according to any one of 2 to 3.   The vibration imparting device is constituted by a concave portion provided in the quantitative supply device main body and a plunger member provided on the measuring plate member side and freely projecting and retracting in the concave portion. 4. The additive component quantitative supply device according to any one of 4 above.   The additive component according to any one of claims 1 to 5, wherein a fan for blowing air toward a lower portion of the drop supply hole is provided above the drop supply hole formed in the additive component supply unit. Metering device.   7. The additive component quantitative supply device according to claim 1, wherein a plurality of metering hole portions of the metering plate member are formed corresponding to the types of additive components.   8. The additive component quantitative supply device according to claim 7, wherein each of the plurality of measurement hole portions has a volume determined in accordance with a measurement value of each additive component to be measured.   9. The additive component quantitative supply device according to claim 1, wherein a plurality of the measuring plate members are formed corresponding to the types of additive components.   The additive component quantitative supply device according to any one of claims 1 to 8, wherein the additive component storage container is configured to be detachable from the quantitative supply device main body.   A fixed quantity supply device for the soup stock, comprising the additive component fixed quantity supply device according to any one of claims 1 to 10.   12. The stock supply quantitative supply device according to claim 11, wherein the additive component quantitative supply device is configured to be detachable with respect to a stock supply quantitative supply device body of the stock supply quantitative supply device.   13. The soup stock supply device according to claim 12, wherein a quantitative feed device body of the additive component quantitative feed device is configured to be detachable with respect to a stock feed quantitative supply device body of the stock juice supply device. Metering device.

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