This invention relates to an electrically powered corkscrew of the kind used for removing corks or stoppers from bottles containing wine, other beverages or food products.
Conventional corkscrews are manually operated. Manual operation may be inconvenient or difficult for users lacking the necessary strength or dexterity. Removal of corks made from plastics material can be especially difficult requiring considerable force, so that there is a risk of spillage or injury to a user.
In the following specification the construction and use of the corkscrew are described in relation to a bottle standing vertically upright. However it should be understood that the corkscrew of this invention may be used to open a bottle inclined to the vertical.
According to a first aspect of the present invention a corkscrew comprises:
Preferably the signal indicates the number of available cork removal cycles. In this way a user can ascertain that a cork can be removed and completely discharged before recharging is required. Removal of a cork from the spiral part way through a cycle may be difficult and hazardous.
Preferably the microprocessor includes a memory arranged to store:
The memory is preferably further arranged to store:
The corkscrew may further include a sensor arranged to provide a signal to the microprocessor indicating the charge state of the battery.
The microprocessor may be arranged to receive a value of the current supplied to the battery and to integrate the value over time to obtain a value of the total charge input to the battery and further arranged to store the total charge input value in the memory.
Preferably the microprocessor is arranged to update the display after each cork removal cycle.
In a further embodiment of the invention the corkscrew may comprise:
According to a second aspect of the present invention, a corkscrew comprises:
In a preferred embodiment the lower sensor may comprise a member which may engage the neck of a bottle and be urged upwardly against the force of a spring means to generate a signal. For example the sensor may comprise an annular member having an upwardly facing conductive portion, the member being biassed by a spring downwardly away from a pair of contacts to form an open circuit, the member being urged upwardly against the force of the spring by contact with the neck of a bottle to close the contacts to generate a signal indicative of the presence of the bottle neck within the socket.
In an alternative embodiment the lower position sensor may comprise a pair of C-shaped members connected by a hinge or an annular member dimensioned to receive the neck of a bottle and arranged to open or dilate upon insertion of the bottle neck, the sensor including a pair of contacts being arranged to disengage to generate a signal indicative of the presence of a bottle neck within the socket.
The upper position sensor may be adapted to detect a cork on the spiral at the top of the socket to generate a signal to stop further rotation of the spiral. In a preferred embodiment the sleeve may engage the upper position sensor when a cork is in the upper position. The upper surface of the sleeve may include an upwardly facing conductive strip. The sensor may comprise a pair of contacts closed by the conductive strip on an upper surface of the sleeve.
The sleeve may comprise an open or closed structure which defines a cylindrical cavity to receive all or part of a cork, preventing rotation of a cork as the spiral rotates. Axially extending splines or other projections may extend into the cavity to engage the surface of the cork.
The sleeve may be composed of rubber or other high friction material. Alternatively the sleeve may be composed of an engineering plastics material and suitably configured to engage the cork in use; for example by provision of splines or other projections which extend into the cavity. Alternatively the sleeve may have a diameter selected to tightly receive and engage the cork preventing rotation as it is withdrawn by the rotating spiral.
The power supply may comprise a rechargeable battery, optionally with a connection to a mains or low voltage power supply. Disposable batteries may be employed.
In a preferred embodiment the corkscrew includes a docking station containing a charging unit for charging the rechargeable batteries when standing by. The docking station may be connected to an external voltage transformer. Each of the corkscrew and docking station may be provided with two metal contacts so that when the corkscrew is placed on the docking station the contacts are engaged. One or more LED's liquid crystal or other displays may be provided on the corkscrew body or on the docking station to indicate the charging status.
The sensors may include a temperature sensor for measuring and monitoring the external temperature of the battery to prevent overheating of the battery. The sensor may also measure and monitor the rate of temperature rise of the battery for reference in charging and discharging the battery.
A voltage sensor may be provided to monitor the input voltage and input current to the battery during charging and the output voltage and output current during use of the corkscrew.
A shake sensor may be provided to detect movement of the corkscrew in order activate the back light of a visual display when the unit is picked up. The shake sensor may comprise a coiled spring and steel or iron needle threaded through the spring. Lightly shaking the corkscrew causes the spring to touch the needle generating a signal to the CPU to activate the system from a stand by state
A digital display can provide an indication of the number of corks which can be removed using the remaining work which can be prepared by the battery. An indication of the number of complete cork removal cycles which can be achieved using the remaining available work is preferably displayed.
In preferred embodiments the display indicates that the corkscrew should be recharged before the battery is fully depleted, preventing the corkscrew from stopping in the middle of a cycle.
Two or more external switches may be provided to actuate the functions of the corkscrew. The switches may be used instead of the lower sensor or as an alternative in situations where manual control is desired for example with long or difficult corks.
A corkscrew in accordance with this invention confers a number of advantages. Physical force or dexterity are not required to operate the corkscrew, and furthermore the corkscrew may be operated with one hand, leaving the other hand free to hold the bottle.
The point of the spiral may not extend beyond the opening of the socket so that accidental injury or damage to a work surface is prevented.
It is an important feature of preferred embodiments of this invention that control means are provided to prevent actuation to remove a cork if the battery is not able to provide sufficient work to complete removal of the cork from the bottle neck and discharge of the removed cork from the spiral. Insufficient available work may result in the cork remaining stuck while still in the bottle or within the body of the corkscrew. In this event, engagement of the corkscrew within a docking station for recharging may be impossible or impeded.
A preferred embodiment of the invention incorporates a control unit. The control unit may comprise a CPU and a battery management control unit. The battery management control unit may be integral with the CPU or may comprise a separate integrated circuit.
The CPU may provide control signals to the motor control circuit or relay to control the forward and reverse motion of the motor.
The battery management circuit may further comprise a sensor adapted to generate a signal dependent on the voltage and/or current drawn by the battery pack. This serves to provide an indication of the available work and the charging condition of the battery.
A DC power supply, for example from a docking station, may include a switch so that no power is supplied to the motor when the battery is charging and so that no power is delivered to the battery when the motor is in use.
The battery management control unit may include a memory arranged to store the value of battery capacity as a function of battery life and the work required to extract an average cork.
The service life of the battery may be stored as a total number of charging and discharging cycles, so that the battery capacity during the service life of the corkscrew is known.
The control unit is preferably adapted to calculate the total number of corks with average tightness which may be opened using a given battery capacity. Each time a cork is removed the battery capacity value is updated by the CPU.
The invention is further described by means of example but not in any limitative sense with reference to the accompanying drawings of which:
The corkscrew shown in
A sleeve (6) having an axial cylindrical bore (7) is mounted on runners (25) for sliding movement in an axial direction within the lower casing (4). A spring (12) urges the sleeve on annular ring (70) downwardly towards the opening of the socket (19). A spring (17) urges a moveable annular sensor ring (8) downwardly so that an upwardly facing metallic contact portion (10) is urged to disengage a pair of contacts (9) to give an open circuit.
When the neck of a bottle (not shown) is inserted into the socket to engage the sensor ring (8), the sensor ring is moved upwardly so that the contacts (9) and (10) are engaged to complete a circuit providing a signal indicating that the corkscrew has engaged the neck of a bottle. The sensor ring and contacts (9) and (10) comprise the lower position sensor.
An LED display (13) located in the top plate (16) beneath a cover (14) of the casing (1) provides a display. The display may show the maximum number of corks which may be removed before the battery becomes depleted.
A metallic strip (40) disposed on axially moveable upper cap (26) cooperates with contacts (41) to form an upper position sensor. The contacts (40) and (41) are engaged when the sleeve (6) and cork (11) are in their uppermost position so that the upper cap (26) is urged upwardly so that the contact strip (40) are pressed into engagement with contacts (41). This provides a signal to the CPU (13).
The operation of the corkscrew is as follows:
In the standby stage the contacts for the upper position indicator are open and the contacts for the lower position indicator are closed. The motor is off.
When a bottle is inserted into the socket, the cork still being within the bottle, the contacts of the upper position sensor are open. The originally closed contacts of the lower position sensor are opened by the engagement with the neck of the bottle. Opening of the contacts sends a signal which actuates the motor so that the spiral is driven in a forward direction causing the point of the spiral to penetrate the cork as the user applies downward pressure on the corkscrew. Rotation continues so that the cork is withdrawn from the bottle as it travels upwardly along the spiral until it is completely removed from the neck of the bottle. The spiral then raises the cork and the sleeve to the upper part of the socket until the sleeve or cork contacts the upper position sensor closing the contacts of the upper position sensor. A signal is sent to the CPU to cause the motor to stop rotation. At this stage the opening of the bottle is completed. The bottle remains within the corkscrew body but the cork has been removed from the bottle and remains on the spiral. The upper position sensor switch contacts are closed and the lower position sensor contacts are open. The motor is turned off.
The bottle may then be removed from the corkscrew. Removal of the neck of the bottle from the socket allows closure of the contacts of the lower position sensor. The signal sent to the CPU causes the motor to rotate in the reverse direction for a limited period sufficient to discharge the cork from the spiral.
The function of this embodiment is similar to the function of the first embodiment.
The arrangement of the sleeve and lower position sensor of the embodiment shown in
An array of switches (36) comprise A and B switches for the upper and lower position sensors respectively, an emergency switch and a reset switch. A current sensor circuit (38) allows control of the charging of the battery (31) and control circuit (39). The power supply to the motor (33) is under the control of the motor control 1C (34).
The number of corks that can be opened is determined by the formula DC/PW. The CPU is arranged to make an adjustment as time goes by based on the BC versus BL data.
Number | Date | Country | Kind |
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0902328.4 | Feb 2009 | GB | national |
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Number | Date | Country | |
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20100206136 A1 | Aug 2010 | US |