KR100813736B1 - Positive displacement pump - Google Patents

Abstract

The present invention relates to a beverage system pump which forms a beverage by pumping a set amount of concentrate from a concentrate vessel into a mixing vessel to mix with water. The pump includes a motor that linearly and rotationally drives the piston. A portion of the piston includes a substantially cylindrical body surface that is received within the compartment of the pump and has a cylindrical surface and an uneven surface. When the concentrate is drawn into the compartment, the uneven surface of the piston is near the inlet of the pump and the cylindrical surface covers the outlet. As the piston moves, the concentrate is drawn into the portion of the compartment formed between the uneven surface of the piston and the wall of the compartment. As a result, the uneven surface of the piston approaches the outlet, and the concentrated liquid trapped between the wall of the compartment and the uneven surface is discharged through the outlet.

Concentrate Distribution Systems, Concentrate Containers, Pumps, Pistons, Motors

Description

Volumetric Pumps {POSITIVE DISPLACEMENT PUMP}

This application claims the priority of US Provisional Application No. 60 / 602,793, filed August 19, 2004.

The present invention relates generally to volumetric pumps used in beverage systems that are not affected by changes in temperature and viscosity of the fluid pumped by the pump.

Beverage systems are used to make beverages and soft drinks. The flavored concentrate is mixed with water to form a beverage. Typically, flavored concentrates are stored in concentrate containers. When the beverage is prepared, the pump draws into the container a set amount of flavored concentrate for serving the beverage. Water is added to the flavored concentrate to form a beverage.

A disadvantage of the beverage systems of the prior art is that the pump is subject to changes in temperature and viscosity of the concentrate. As the temperature of the concentrate decreases, the viscosity increases, reducing the flow rate of the concentrate through the pump. That is, the pump output depends on the product viscosity. Therefore, as the temperature of the concentrate decreases, the pumping rate of the pump must increase to compensate for the decrease in flow of the concentrate. This is undesirable because decreasing the flow rate of the pump may dilute the beverage and affect product quality.

Therefore, there is a need in the art for a volumetric pump that compensates for the drawbacks and drawbacks of the prior art without being affected by changes in temperature and viscosity of the pumped fluid.

The beverage system includes a concentrate container including a flavored concentrate and a fluid container including water. The pump pumps a set amount of the concentrate from the concentrate vessel into the mixing vessel. In addition, water from the fluid vessel is added to the mixing vessel. The concentrate and water are mixed to form a beverage.

The pump controls the flow of the concentrate to the mixing vessel. The pump includes a motor used to construct a motor shaft including a piston interface knuckle. The piston interface knuckle is coupled to the piston. When the motor shaft is rotated, the piston moves and rotates linearly due to the combination of the piston and the piston interface knuckle.

A portion of the piston is received in the compartment of the pump. The compartment has a fixed volume and cannot be expanded. The movement of the piston by the motor draws in a set amount of concentrate through the inlet into the compartment and releases the concentrate from the inlet through the outlet. The portion of the piston housed in the compartment includes a cylindrical body having a cylindrical surface and an uneven surface. The uneven surface may be flat or U-shaped.

When the concentrate is drawn into the compartment, the piston is rotated by the motor so that the uneven surface is near the inlet of the pump. As the piston moves linearly and rotationally, the concentrate is drawn into the portion of the compartment formed between the wall of the compartment and the uneven surface of the piston. The cylindrical body portion is coupled to the outlet to prevent the concentrate from being discharged through the outlet.

As the piston continues to rotate, the concentrate confined between the walls of the compartment and the uneven surface of the piston moves from the inlet to the outlet. The cylindrical body portion of the piston is eventually coupled to the inlet, preventing further concentrate from being drawn into the pump. The uneven surface of the piston eventually approaches the outlet, and the concentrated liquid trapped between the uneven surface and the wall of the compartment is discharged through the outlet. The concentrate can then be mixed with water in a mixing vessel to form a beverage.

These and other features of the present invention will be better understood from the following detailed description and drawings.

Various features and effects of the present invention will become apparent to those skilled in the art from the following detailed description of the presently preferred embodiments. The drawings that accompany the detailed description can be briefly described as follows.

1 schematically shows a front view of a beverage system used to make a beverage.

2 shows a cross-sectional perspective view of the pump of the present invention.

Figure 3 shows a perspective view of a first embodiment of a pump piston of the present invention.

4 shows a perspective view of a second embodiment of a pump piston of the invention.

5 shows a sectional view of the piston movement during operation of the pump.

1 schematically shows a beverage system 22 of the present invention. The beverage system 22 is used to make beverages, soft drinks, milkshakes, dairy products or other frozen desserts. The beverage system 22 includes a concentrate container 24 that includes a flavored concentrate 52. The pump 20 sucks the set amount of the concentrate 52 from the concentrate container 24 to the inlet 30 of the pump 20. The pump 20 controls the flow of the concentrate 52, and the concentrate 52 exits the pump 20 through the outlet 32. Thereafter, the popped concentrate 52 enters the mixing vessel 50. In addition, water contained in the water vessel 26 is added to the mixing vessel 50 and mixed with the concentrate 52 to form a beverage. The beverage is then added to the cup 28 for beverage delivery.

2 schematically shows a pump 20 of the present invention. The pump 20 includes a motor 34 that is used to drive the motor shaft 36. Motor shaft 36 includes a piston interface knuckle 38. When the motor shaft 36 is rotated, the attached piston interface knuckle 38 is also rotated. The piston interface knuckle 38 is coupled to the piston 40. As the motor shaft 36 is rotated, the piston 40 is linearly moved and rotated due to the combination of the piston 40 and the piston interface knuckle 38. That is, the piston 40 is driven in the long motion.

A portion 42 of the piston 40 is received in the compartment 44 of the pump 20. Compartment 44 has a fixed volume and does not expand or contract during operation of pump 20. Preferably, compartment 44 is made of steel. Movement of the piston 40 by the motor 34 sucks the concentrate into the compartment 44 through the inlet 30 and discharges the concentrate from the compartment 44 through the outlet 32. A portion 42 of the piston 40 received in the compartment 44 is substantially cylindrical in shape and includes a cylindrical surface 48 having an uneven surface 46. As shown in FIG. 3, the uneven surface 46 may be a flat surface. Alternatively, as shown in FIG. 4, the uneven surface 46 may be a cup-shaped or U-shaped surface. A space is formed between the uneven surface 46 of the piston 40 and the wall of the compartment 44.

As shown in FIG. 5, when the set amount of the concentrate 52 is sucked into the compartment 44, the piston 40 has the uneven surface 46 of the piston 40 near the inlet 30 of the pump 20. As shown in FIG. It is rotated by the motor 34 so as to be. Since the uneven surface 46 is spaced from the inlet 30, the set amount of the concentrate 52 can be sucked into the space formed between the wall of the compartment 44 and the uneven surface 46 of the piston 40. As the piston 40 continues to rotate, the concave-convex surface 46 moves away from the inlet 30 toward the outlet 32 and continues to draw the concentrate 52 into the compartment 44. At this time, the cylindrical surface 48 is coupled to the outlet 32 to prevent the concentrate 52 from being discharged through the outlet 32.

As the piston 40 continues to rotate, the concentrate 52 trapped in the space between the uneven surface 46 of the piston 40 and the wall of the compartment 44 moves from the inlet 30 toward the outlet 32. do. As a result, the cylindrical surface 48 of the piston 40 is coupled to the inlet 30 to prevent additional concentrate 52 from being drawn into the pump 20. The concave-convex surface 46 of the piston 40 eventually approaches the outlet 32 so that the concentrated liquid trapped in the space between the concave-convex surface 46 and the wall of the compartment 44 is discharged through the outlet 32. Concentrate 52 may then be mixed with water in mixing vessel 50 to form a beverage.

As the additional concentrate 52 is drawn into the pump 20, the piston 40 is rotated such that the uneven surface 46 approaches the inlet 30 again, so that the additional concentrate 52 is transferred to the compartment 44. Aspirated. Thereafter, the cycle is repeated to discharge the concentrate 52 from the outlet 32 of the pump 20.

Since the pump 20 of the present invention does not contain any expandable components, the speed of the pump 20 does not change if there is any change in the viscosity or temperature of the concentrate 52. That is, because compartment 44 is made of steel, compartment 44 has a fixed volume and a fixed shape. Accordingly, the pump 20 of the present invention adjusts the speed of the pump 20 as the temperature and viscosity of the concentrate 52 is changed to transfer a predetermined amount of the concentrate 52, and adjusts the viscosity or temperature of the concentrate 52. No adjustment motor is needed to compensate for the change. In addition, the pump 20 minimizes the operator interface required for the beverage system 22, thereby reducing the total cost of the beverage system 22 and improving product consistency.

While the beverage system 22 is shown and described, the pump 20 of the present invention can be used in other systems. For example, the pump 20 can be used in a soft drink system. In this example, pump 20 pumps the flavored syrup that is mixed with the carbonated water to form a soft drink.

The foregoing detailed description is merely illustrative of the principles of the invention. Various modifications and variations can be made in light of the above teachings. Accordingly, within the scope of the following claims, the invention may be practiced otherwise than using the specifically described exemplary embodiments. For this reason, the following claims should be considered to determine the true scope and content of this invention.

Claims (18)

A concentrate container for storing the concentrate; A pump for controlling the flow of the concentrate from the concentrate vessel, the pump comprising a housing having a compartment, an inlet and an outlet, the pump further comprising a piston having a cylindrical surface and an uneven surface, a portion of the piston Housed in a compartment, wherein the piston is adjacent to the inlet when the uneven surface is adjacent to the inlet when the pump draws the concentrate into the compartment and when the pump discharges the concentrate out of the compartment. A pump that can be moved to A concentrate dispensing system comprising a motor to move a piston. The concentrate distribution system of claim 1 wherein the uneven surface is substantially flat. The concentrate distribution system of claim 1 wherein the uneven surface is substantially U-shaped. The concentrate distribution system of claim 1 wherein the housing is made of steel. The concentrate distribution system of claim 1 wherein said housing is non-expandable. The concentrate distribution system of claim 1 wherein the pump draws the concentrate from the concentrate vessel into a mixing vessel. 7. The concentrate dispensing system of claim 6, further comprising a fluid vessel containing a fluid, wherein the fluid is mixed with the concentrate in the mixing vessel. 8. The concentrate dispensing system of claim 7, wherein said fluid is water. The concentrate distribution system of claim 1 wherein the motor comprises a motor shaft having a piston interface knuckle, wherein rotation of the motor shaft rotates the piston interface knuckle. 10. The concentrate distribution system of claim 9 wherein the piston interface knuckle is coupled to a piston to move the piston. The concentrate distribution system of claim 1 wherein the piston is in linear and rotational motion. The surface of claim 1, wherein during the suction of the concentrate, the uneven surface is near the inlet, and the movement of the piston sucks the concentrate through the inlet into the space formed by the uneven surface and the compartment and the cylindrical surface. Is coupled to the outlet to prevent the concentrate from flowing through the outlet. The method of claim 1, wherein during the discharge of the concentrate, the uneven surface is near the outlet, and the movement of the piston draws the concentrate out of the space formed by the uneven surface and the compartment and the cylindrical surface is the concentrate. And a concentrate distribution system coupled to the inlet to prevent it from entering the inlet. The concentrate distribution system of claim 1 wherein the movement of the piston moves the concentrate from the inlet to the outlet. A concentrate container for storing the concentrate; A fluid container for storing fluid, A pump for controlling the flow of the concentrate from the concentrate vessel, the pump including a non-expandable housing having a compartment, an inlet and an outlet, the pump further comprising a piston having a cylindrical surface and an uneven surface, the portion of the piston Is received in the compartment, and the piston has the uneven surface adjacent to the inlet when the pump draws the concentrate into the compartment and the uneven surface exits the outlet when the pump discharges the concentrate out of the compartment. A pump that can be moved adjacent to, A motor for moving a piston, the motor comprising a motor shaft having a piston interface knuckle, wherein rotation of the motor shaft rotates the piston interface knuckle, and the piston interface knuckle is coupled to the piston to move the piston. Motor, A mixing vessel, The concentrate pumped by the pump and the fluid from the fluid vessel are mixed in the mixing vessel. The concentrate distribution system of claim 15 wherein said uneven surface is substantially flat. The concentrate distribution system of claim 15 wherein said concave-convex surface is substantially U-shaped. 16. The concentrate distribution system of claim 15 wherein the piston is in linear and rotational motion.

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