KR101269434B1 - Refrigerating cylinder of ice cream having cooling air supply and ice cream manufacturing device having the same - Google Patents

Abstract

The present invention is a cylinder body having a cooling space for the yoghurt ice cream stock solution, a stirring unit rotatably installed inside the cylinder body, a stirring unit for stirring the yoghurt ice cream stock solution by a rotational drive, and installed on the outer peripheral surface of the cylinder body A cooling jacket providing a moving space of the refrigerant to cool the cylinder body; And a cooling cylinder of the yoghurt ice cream installed in the cylinder body and including a cooling air injection tube for injecting cooling air into the cylinder body, and an ice cream manufacturing apparatus having the same.

Description

REFRIGERATING CYLINDER OF ICE CREAM HAVING COOLING AIR SUPPLY AND ICE CREAM MANUFACTURING DEVICE HAVING THE SAME}

The present invention relates to a cooling cylinder for ice cream for cooling and stirring the ice cream stock solution and an ice cream manufacturing apparatus having the same.

Ice cream manufacturing apparatus refers to a device that mixes and cools the ice cream stock with air to provide a soft ice cream ice cream. In general, the ice cream manufacturing apparatus includes a storage tank (hopper) for storing and mixing the ice cream stock solution, a cooling cylinder for mixing and cooling the ice cream stock solution with air, and a discharge mechanism for discharging the ice cream of the cooling cylinder to the outside. Have

The ice cream stock solution of the reservoir is supplied to the cooling cylinder, and the wall of the cooling cylinder is cooled with the refrigerant to exchange heat with the ice cream stock solution therein. As described above, according to the cooling method of transferring the refrigerant to the jacket of the cooling cylinder, the temperature near the wall of the cooling cylinder is very low while the temperature of the center of the cooling cylinder is relatively high, so that the temperature distribution inside the cooling cylinder is not constant. This may cause a problem that the ice cream in the center of the cooling cylinder is not properly cooled, there is a problem that the temperature of the refrigerant is excessively lowered to solve this problem.

In addition, by stirring the ice cream using a stirrer in the ice cream cooling process as described above so that the ice cream and air is combined. Due to the injection of air during freezing of the ice cream, the ice cream swells during the combination of ice cream and air due to the formation of bubbles and diffusion of ice crystals. This is called. The principle of the occurrence of overrun is that during the mixing and mixing of the ice cream solution cooled from the cylinder wall with a stirrer, the outer wall surrounding the fat contained in the ice cream is collapsed and recombined by external factors such as shear force. It is a phenomenon that occurs while enclosing air to maintain structure. In this case, the overrun may refer to a rate at which the volume of the ice cream is increased, and the overrun is an important factor in determining the texture of the ice cream. In the case of yoghurt ice cream, it is known that 40-50% of the overrun is suitable.

In the process of mixing the ice cream and air, the ice cream swells and the volume increases, which is called an overrun. An overrun is also referred to as an increase in the volume of the ice cream, which is an important factor in determining the texture of the ice cream. In the case of yoghurt ice cream, it is known that 40-50% of the overrun is suitable.

The organization of the ice cream is determined by the size of the ice crystals, the size and distribution of the bubbles, and the size of the unfrozen particles of the ice cream. As the temperature of the ice cream solution decreases, the viscosity increases, but the intrinsic viscosity decreases due to a change in gel structure or fat spheres by rapid stirring.

The present invention has been made in view of the above, by cooling the inner wall of the cooling cylinder and by introducing cooling air into the interior of the cooling cylinder, three-dimensional cooling of the inside of the cooling cylinder is achieved, as well as overrun increase and ice cream. This is to improve the texture of the.

In order to achieve the above object, the present invention provides a cylinder body having a cooling space for ice cream stock solution, a stirring unit rotatably installed inside the cylinder body, and agitating the ice cream stock solution by rotational driving, and the cylinder. Cooling of ice cream, which is installed on the outer circumferential surface of the body and provides a cooling jacket for providing a moving space of the refrigerant to cool the cylinder body, and a cooling air inlet tube installed in the cylinder body to inject cooling air into the cylinder body. Disclosed is a cylinder and an ice cream manufacturing device having the same.

First and second through holes are formed on the outer circumferential surfaces of the cylinder body and the cooling jacket, respectively, and the cooling air injection pipe is inserted into the first and second through holes to exchange heat with the refrigerant. May have

The cooling air injection pipe may be installed on the upper portion of the cylinder.

The cooling air inlet pipe may be installed to be inclined in a direction opposite to the transport direction of the stirred ice cream.

The cooling air inlet pipe is connected to an air supply for supplying air, and the air supply is configurable to maintain the pressure of the cooling air inlet pipe at normal pressure.

According to the present invention having the configuration described above, by cooling the main body itself through the refrigerant and at the same time supplying cooling air to the inside of the cylinder body it is possible to three-dimensional cooling of the ice cream stock solution during the process of combining with the ice cream stock solution, thereby The temperature distribution can be made uniform, so that more effective cooling can be achieved.

In addition, the cooling air injected through the cooling air inlet tube not only helps to generate an overrun of the ice cream, but also functions to improve the texture (cold taste) of the ice cream. In other words, the ice cream melts frozen in the mouth, heat exchanges in the mouth, and feels cold.However, when the ice cream solution is combined with cold air by injecting cold air, the effect of the cold texture tastes in the mouth. Will be added.

In addition, more efficient energy use is possible by heat-exchanging the refrigerant introduced into the cooling jacket with the air introduced through the cooling air injection pipe.

In addition, through the inclined shape of the cooling air injection pipe and the structure extending to the inside of the cylinder body, it is possible to minimize the phenomenon that the ice cream flows back into the cooling air injection pipe.

1 is a view schematically showing an apparatus for producing yoghurt ice cream according to the present invention.
2 is a perspective view of a cooling cylinder according to an embodiment of the present invention.
3 is an exploded perspective view of the cooling cylinder shown in FIG.
4 is a side cross-sectional view of the cooling cylinder shown in FIG.
5 is a side cross-sectional view of a cooling cylinder according to another embodiment of the present invention.

Hereinafter, a cooling cylinder of yoghurt ice cream and an apparatus for producing yoghurt ice cream having the same according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a view schematically showing an ice cream manufacturing apparatus according to the present invention.

Ice cream manufacturing apparatus according to an embodiment of the present invention is a hopper (100) for mixing the ingredients of yogurt ice cream (milk, lactic acid bacteria material, yogurt, etc.) and the refrigerant for cooling the yogurt ice cream stock solution formed by mixing the materials It includes a refrigerant supply unit (not shown) for supplying, and a cooling cylinder 200 for mixing and cooling the yoghurt ice cream stock solution with air.

The hopper 100 includes a reservoir 110 for storing the material of the yoghurt ice cream, a shaft 120 driven to rotate in the reservoir 110, and a stirrer 130 coupled to the shaft 120. The shaft 120 is connected to the hopper driving motor 140 and driven to rotate, and the stirrer 130 rotates as the shaft 120 rotates to stir the yoghurt ice cream material.

The refrigerant supply unit is implemented as a general refrigeration cycle and has a configuration including a compressor, a condenser, an expansion valve, and an evaporator. The refrigerant passing through the evaporator is supplied to the cooling cylinder 200 to cool the yoghurt ice cream stock solution.

The cooling cylinder 200 communicates with the hopper 100 to receive the yoghurt ice cream stock solution of the storage tank 110, and cools the yogurt ice cream stock solution through the coolant supplied from the coolant supply unit and mixes the stock solution with air.

The rear of the cooling cylinder 200 is provided with a discharge mechanism 400 for discharging the completed yogurt ice cream to the outside. As an example of the discharge mechanism 400, a configuration including a case 410 having a flow path communicating with the cooling cylinder 200, and a lever 420 for opening and closing the flow path of the case 410 by a user's operation Can be mentioned.

2 is a perspective view of a cooling cylinder according to an embodiment of the present invention.

Referring to FIG. 2, the cooling cylinder 200 includes a cylinder body 210 having a cooling space for the yoghurt ice cream stock solution, and a stirring unit for stirring and transferring the yoghurt ice cream stock solution by rotational driving.

The cylinder body 210 includes an inlet 213 of the yoghurt ice cream stock solution in front of the cylinder body 210. The rear of the cylinder body 210 communicates with the discharge port 214 formed in the case 410 of the discharge mechanism 400. In FIG. 2, the cylinder body 210 is indicated by a dotted line to show the internal parts of the cylinder body 210.

The outer circumferential surface of the cylinder body 210 is provided with a cooling jacket 211 providing a moving space of the refrigerant. The cooling jacket 211 is formed in a cylinder shape to seal the moving space of the refrigerant.

The coolant jacket 211 is provided with a coolant inlet 215 and a coolant discharge port 216 for inflow and discharge of the coolant. The coolant inlet 215 may be formed at any one of a front upper side and a rear bottom lower side of the coolant jacket 211, and the coolant discharge port 216 may be formed at another one of a front upper side and a rear lower side of the coolant jacket 211. This embodiment illustrates that the coolant inlet 215 is formed below the rear end of the coolant jacket 211 and the coolant discharge port 216 is formed above the front of the coolant jacket.

The stirring unit includes first and second holders 220 and 230 and a blade 240.

The first and second holders 220 and 230 are rotatably installed in the cylinder body 210. The first and second holders 220 and 230 are installed to be spaced apart from each other by the cylinder body 210.

The blade 240 is fixed between the first and second holders 220 and 230 and functions to agitate the yoghurt ice cream stock solution by a rotation operation. The blade 240 has a curved shape in a spiral shape and may be provided in a singular or plural number between the first and second holders 220 and 230.

The first holder 220 is connected to the shaft 228 extending through the front of the cylinder body 210 to the outside. The end of the shaft 228 is connected to the cooling cylinder driving motor 300 (see FIG. 1) by a belt pulley 350 (see FIG. 1), and the blade (see FIG. 1) according to the cooling cylinder driving motor 300 (see FIG. 1). 240 is rotated.

An impeller 260 for transferring the yoghurt ice cream stirred by the blade 240 to the discharge port 214 may be further installed at the rear of the second holder 230. Impeller 260 is a structure formed with a screw on the outer periphery, rotatably supported by the case 410 located behind it.

3 is an exploded perspective view of the cooling cylinder shown in FIG. 2, and FIG. 4 is a side cross-sectional view of the cooling cylinder shown in FIG. 2. For reference, illustration of the components of the stirring unit is omitted in FIG.

3 and 4, the cylinder body 210 is provided with a cooling air injection tube 530 for injecting cooling air into the cylinder body 210.

As shown in FIG. 4, since the yoghurt ice cream stock is filled to a certain height from the bottom of the cylinder body 210, in order to prevent the overrun ice cream from flowing back into the cooling air injection pipe 530, the cooling air injection pipe 530. ) Is preferably installed on the upper portion of the cylinder body (210). According to this, the cooling air of the cooling air injection pipe 530 is injected toward the inner space from the upper inner wall of the cylinder body 210.

According to this embodiment, the first through hole 510 is formed on the outer circumferential surface of the cylinder body 210, and the second through hole 520 is formed on the outer circumferential surface of the cooling jacket 211. In this case, the cooling air injection pipe 530 is inserted into the first and second through holes 510 and 520. The first and second through holes 510.520 are formed at positions corresponding to each other, and the cooling air injection pipe 530 serves to supply external air into the cylinder body 210.

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The other end of the cooling air injection pipe 530 may be installed with a tube 540 connected to the air supply. However, the present invention is not limited to this form, the cooling air inlet pipe 530 is configured in the form of a tube, it will be possible to also be configured to connect it directly to the air supply.

The air supply is preferably configured to maintain the pressure of the cooling air inlet pipe 530 at atmospheric pressure. When the overrun ice cream flows into the cooling air injection pipe 530, the pressure of the cooling air injection pipe 530 serves to push the ice cream.

Hereinafter will be described the operating mechanism of the cooling cylinder according to an embodiment of the present invention.

The coolant R introduced from the coolant inlet 215 is discharged to the coolant discharge port 216 after moving the space between the cylinder body 210 and the cooling jacket 211. In this process, the cylinder body 210 is cooled, and the ice cream inside the cylinder body 210 is cooled according to the cooling of the cylinder body 210.

The air supplied to the cooling air inlet pipe 530 is cooled while being heat-exchanged with the refrigerant R between the cylinder body 210 and the cooling jacket 211 during the movement thereof, thereby cooling the inside of the cylinder body 210. The air will be supplied.

In this way, by cooling the cylinder body 210 itself and supplying cooling air into the cylinder body 210, three-dimensional cooling of the ice cream is possible. According to the three-dimensional cooling can be uniform temperature distribution in the cylinder body 210 can be more effective cooling.

In addition, as the blade 240 rotates, the ice cream is agitated to generate an overrun, and the air injected through the cooling air inlet pipe 530 helps to generate such an overrun. That is, due to the air injected through the cooling air inlet tube 530, the temperature of the air mixed with the ice cream is reduced, and the overrun in the cylinder is made uniform because the cooled air helps the cooling of the ice cream.

In addition, the texture (cold taste) of the ice cream is affected by the mixed air at the time of overrun as well as the low temperature of the ice cream itself. According to the present invention, by allowing the cold cooling air to be mixed with the ice cream stock solution, it is possible to add a cold taste and to make the cold taste last longer.

5 is a side cross-sectional view of a cooling cylinder according to another embodiment of the present invention.

The cooling cylinder of this embodiment has the same configuration as in the previous embodiment except for the configuration of the cooling air injection pipe 530 '. The cooling air injection pipe 530 ′ of the present embodiment is installed to be inclined in a direction opposite to the conveying direction (progression direction P) of the stirred ice cream. In this case, the first through hole 510 'is formed behind the second through hole 520' at a predetermined interval.

As such, by installing the cooling air inlet tube 530 'to be inclined, a phenomenon in which the ice cream flows back into the cooling air inlet tube 530' can be minimized as compared with the previous embodiment.

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In the above, the cooling air injection tube is illustrated as a configuration in which cooling air is injected into the cylinder body, but the present invention is not limited thereto, and the configuration for supplying cooling air into the cylinder body 510 may be implemented in other forms. something to do. In addition, the cooling cylinder of the present invention is applicable to not only yogurt ice cream but also various kinds of ice cream.

In addition, the cooling cylinder of the yogurt ice cream and the yogurt ice cream manufacturing apparatus having the same according to the present invention is not limited by the embodiments and drawings disclosed herein, various modifications by those skilled in the art within the scope of the technical idea of the present invention Can be done.

Claims (7)

A cylinder body having a cooling space of the ice cream stock solution; And
A stirring unit rotatably installed in the cylinder body and for stirring the ice cream stock solution by a rotational drive;
A cooling jacket installed on an outer circumferential surface of the cylinder body and providing a moving space of the refrigerant to cool the cylinder body; And
Cooling cylinder of the ice cream is installed in the cylinder body, comprising a cooling air injection pipe for injecting cooling air into the interior of the cylinder body. The method of claim 1,
First and second through holes are formed on the outer circumferential surfaces of the cylinder body and the cooling jacket, respectively.
The cooling air injection tube is a cooling cylinder of the ice cream, characterized in that the air inside is inserted into the first and second through-hole so that the heat exchange with the refrigerant. The method of claim 1,
The cooling air injection tube is the cooling cylinder of the ice cream, characterized in that installed on top of the cylinder. delete The method of claim 3,
The cooling air inlet pipe is a cooling cylinder of the ice cream, characterized in that installed to be inclined in a direction opposite to the conveying direction of the stirred ice cream. The method of claim 3,
The cooling air inlet pipe is connected to the air supply for air supply,
The air supply cooling cylinder of the ice cream, characterized in that configured to maintain the pressure of the cooling air inlet tube at normal pressure. A hopper for mixing the ice cream material;
A refrigerant supply unit supplying a refrigerant for cooling the ice cream stock solution in which the material is mixed; And
And a cooling cylinder configured to communicate with the hopper to receive the ice cream of the hopper and to cool the ice cream through the refrigerant provided by the refrigerant supply unit.

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