METHOD FOR WATERPROOFING A LOCK DEVICE

Abstract

A method for waterproofmg a lock device includes applying a hydrophobic coating on internal components of a lock device, the components including a movable plug and plug pins.

Description

FIELD OF THE INVENTION

The present invention generally relates to lock devices, such as mechanical and electromechanical locks, and more specifically to protecting such locks with a hydrophobic coating.

BACKGROUND OF THE INVENTION

There are many situations where it is desired to prevent water from entering a cylinder lock or other similar lock device. For example, water entering a cylinder lock can cause corrosion in the plug, plug pins or driver pins and prevent proper operation of the cylinder lock. In electromechanical locks, there is the additional problem of water contacting electrical circuitry and causing short circuits.

The problem of waterproofing a cylinder lock has been addressed in the prior art. The typical prior art solution is the use of a sealing device, such as a seal, gasket or other sealing member, which seals the entrance to the keyway in the lock. This solution is deficient for several reasons. For example, if the seal just covers the keyway opening, it does not seal the space between the cylinder lock plug and the cylinder housing and water can enter. Even if the seal covers the entire entrance to the cylinder lock, the seal must be removed before using the lock which makes the solution cumbersome to use. The seal can also fall off or get lost. Even worse, if water gets past the seal, the seal prevents the water from exiting, thereby accelerating corrosion formation.

SUMMARY OF THE INVENTION

The present invention seeks to provide an improved method for waterproofing a cylinder lock, padlock and the like, with a hydrophobic coating, as is described in detail further hereinbelow. The invention may be used for mechanical, mechatronic and electromechanical lock devices. The hydrophobic coating is thin and does not significantly add to the outer dimensions of the components and of the lock device. This is an important advantage over the prior art. The components and lock device can fit into a volume that the prior art cannot achieve.

Examples of lock devices for which the invention is applicable include, without limitation, mechanical padlocks or cylinder locks, mechatronic padlocks or cylinder locks and electromechanical padlocks or cylinder locks,

A mechatronic padlock is a device with an integrated or a remote electronic system, which operates after verifying the authorization of a user.

A mechatronic cylinder lock is a device with an integrated or a remote electronic system, which is to be used with a lock for the purpose of operating the lock after verifying the authorization of an electronic key.

The invention is applicable for electronic or electromechanical keys and remote control devices, such as keypads, fingerprint sensor devices for locks, RFID (radio frequency identification), RC (radio or remote control) and others. The hydrophobic coating does away for the need for caps or other seals.

The hydrophobic coating can be optically transparent or RF transparent and therefore suitable for covering optical elements, such as LEDs, or RF components, such as transceivers or transducers.

Electromechanical locking devices require contacts that interface with a key device. In the prior art, the contacts are protected from water or other moisture by a removable cap or other seal in the keyway. The use of the cap depends on the user. There are situations where the cap must be removed even if rain is falling on the lock device. The hydrophobic coating does away for the need for caps or other seals. Even if water enters the device, the hydrophobic coating protects the components.

There is thus provided in accordance with an embodiment of the present invention a method for waterproofing a lock device including applying a hydrophobic coating on internal components of a lock device, the components including a movable plug and plug pins. The components may further include driver pins and springs, bolt throwing elements and/or electrical components.

In accordance with an embodiment of the present invention the hydrophobic coating is applied on the internal components after the internal components are assembled in the lock device.

In accordance with another embodiment of the present invention the hydrophobic coating is applied on the internal components before the internal components are assembled in the lock device.

The lock device may include a mechanical lock, an electromechanical lock, a cylinder lock, a padlock, or a key (e.g., an electronic or electromechanical key).

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will be understood and appreciated more fully from the following detailed description taken in conjunction with the drawing in which:

FIG. 1 is a simplified flow chart of a method for waterproofing a lock device in accordance with a non-limiting embodiment of the present invention.

DETAILED DESCRIPTION OF EMBODIMENTS

Reference is now made to FIG. 1, which illustrates a method for waterproofing a lock device in accordance with a non-limiting embodiment of the present invention.

In contrast with the prior art methods of sealing to prevent ingress of water into the lock, in the present invention, no attempt is made to prevent water from entering. Instead waterproof protection is provided by application of a hydrophobic coating on some or all of the inner components of the lock device. Examples are given below for applying the hydrophobic coating.

In one embodiment, the hydrophobic coating is applied on the internal components of the lock device before the internal components are assembled in the lock device. For example, for a mechanical lock device, the movable (e.g., rotatable) plug, plug pins, driver pins, springs and bolt throwing elements (such as latches, cams, levers, etc.) are coated with a hydrophobic coating and then assembled in the lock. For an electromechanical or mechatronic lock device, in addition to any movable plug, plug pins, driver pins, springs and bolt throwing elements (such as latches, cams, levers, etc.), any electrical components (e.g., motor, actuator, solenoid and the like) and/or printed circuit boards are coated with a hydrophobic coating and then assembled in the lock.

In another embodiment, the hydrophobic coating is applied on the internal components of the lock device after the internal components are assembled in the lock device. For example, for a mechanical lock device, the plug, plug pins, driver pins, springs and cam or cams are coated with a hydrophobic coating after having been assembled in the lock. For an electromechanical or mechatronic lock device, in addition to any plug, plug pins, driver pins, springs and cam or cams, any electrical components and/or printed circuit boards are coated with a hydrophobic coating after having been assembled in the lock. This embodiment has the advantage of significant savings in time and money. In addition, this embodiment has the advantage of being applicable to lock devices that have been previously manufactured and for which it is desired to waterproof.

In yet another embodiment, the hydrophobic coating is applied on an electromechanical key, defined as a key on which key cuts are to be cut for interfacing with elements when the key is inserted in a keyway of a lock device and which includes electrical/electronic components for effecting authorization of the key with the lock device. The hydrophobic coating protects electrical/electronic components of the electromechanical key from damaging effects of moisture.

Examples of method for applying the hydrophobic coating include, without limitation, chemical and physical coating processes, such as sol-gel coating processes. The solution (“sol”) gradually forms a gel-like diphasic system (“gel”) containing hydrophobic nano-particles which are included within a polymer network. These nano-particles coat the component surfaces. The coating is applied by using simple dipping (such as dipping the completely assembled lock device in the hydrophobic solution or dipping the individual components in the solution before assembly) or spraying processes (such as spraying the completely assembled lock device with the hydrophobic solution, wherein the sprayed solution covers the components by flowing into the lock device, or spraying the individual components with the solution before assembly) followed by a hardening process. In principal, all those coatings can be applied to all kind of materials which can withstand the necessary temperatures for the hardening process, and is thus applicable for both mechanical and electromechanical locks.

An example of such a sol-gel hydrophobic coating is described in PCT patent application WO 03/094574. The example is a biofilm-inhibiting coating of an inorganic condensate modified with organic groups on the basis of a coating composition, which includes a hydrolysate or pre-condensate of one or more hydrolysable compounds with at least one non-hydrolysable substituent, whereby at least one part of the organic groups of the condensate exhibits fluorine atoms and/or copper or silver colloids are contained in the coating.

Other examples of hydrophobic coatings include, without limitation, different silicone compounds, such as silicone polymers, poly-metric siloxanes, reactive silane monomers, siliconates, hydrated silanes (hydro-silicones), organic silicon-containing materials and others. Silicone compounds may be dissolved or thinned with a liquid solvent and the mixed solution or emulsion is sprayed onto the components or finished assembly, followed by drying.

Another example of a suitable hydrophobic conformal coating is a chemical vapor deposition (CVD) process. There are many types of CVD processes, which can be used to carry out the invention, including but not limited to, atmospheric CVD, low pressure CVD, ultra-high vacuum CVD and different kinds of plasma-assisted CVD. The invention is not limited to any particular process. The hydrophobic coating can be between 1 and 3 microns thick, or other thicknesses depending on the need and application. An example of a hydrophobic coating is a parylene coating.

The terms waterproof, water-resistant and water-repelling are used interchangeably in the specification and claims.

The International Electrotechnical Commission (IEC) standard 60529, inter alia, defines degrees of protection against water. The following table summarizes the levels of protection:

	Protected
Level	against	Testing for	Details
0	Not	—	—
	protected
1	Dripping	Dripping water (vertically	Test duration: 10
	water	falling drops) shall have	minutes
		no harmful effect.	Water equivalent
			to 1 mm rainfall
			per minute
2	Dripping	Vertically dripping water	Test duration: 10
	water	shall have no harmful	minutes
	when	effect when the enclosure	Water equivalent
	tilted	is tilted at an angle up	to 3 mm rainfall
	up to	to 15° from its normal	per minute
	15°	position.
3	Spraying	Water falling as a spray	Test duration: 5
	water	at any angle up to 60°	minutes
		from the vertical shall	Water volume per
		have no harmful effect.	time: 0.7 lit/min
			Pressure: 80-100
			kPa
4	Splashing	Water splashing against	Test duration: 5
	of water	the enclosure from any	minutes
		direction shall have no	Water volume per
		harmful effect.	time: 10 lit/min
			Pressure: 80-100
			kPa
5	Water	Water projected by a	Test duration: at
	jets	nozzle (6.3 mm) against	least 3 minutes
		enclosure from any	Water volume per
		direction shall have no	time: 12.5 lit/min
		harmful effects.	Pressure: 30 kPa
			at distance of 3 m
6	Powerful	Water projected in	Test duration: at
	water	powerful jets (12.5 mm	least 3 minutes
	jets	nozzle) against the	Water volume per
		enclosure from any	time: 100 lit/min
		direction shall have	Pressure: 100 kPa
		no harmful effects.	at distance of 3 m
6K	Powerful	Water projected in	Test duration: at
	water	powerful jets (6.3 mm	least 3 minutes
	jets with	nozzle) against the	Water volume per
	increased	enclosure from any	time: 75 lit/min
	pressure	direction, under	Pressure: 1000 kPa
		elevated pressure,	at distance of 3 m
		shall have no
		harmful effects.
7	Immersion	Ingress of water in	Test duration: 30
	up to 1 m	harmful quantity	minutes
		shall not be possible	The lowest point
		when the enclosure	of enclosures with
		is immersed in water	a height less than
		under defined	850 mm is located
		conditions of pressure	1000 mm below the
		and time (up to 1 m	surface of the
		of submersion).	water, the highest
			point of enclosures
			with a height equal
			to or greater than
			850 mm is located
			150 mm below the
			surface of the
			water
8	Immersion	The equipment is	Test duration:
	beyond	suitable for continuous	continuous
	1 m	immersion in water	immersion in water
		under conditions which	Depth specified
		shall be specified by	by manufacturer,
		the manufacturer.	generally up to
		However, with certain	3 m
		types of equipment, it
		can mean that water can
		enter but only in such
		a manner that it
		produces no harmful
		effects.
9K	Powerful	Protected against	—
	high	close-range high
	temper-	pressure, high
	ature	temperature spray
	water	downs.
	jets

The waterproofing achieved with the methods of the invention can be used to comply with IEC standard 60529 levels 1-6K, or to levels 1-8 or to levels 1-9K.

Claims

1. A method for waterproofing a lock device comprising: applying a hydrophobic coating on internal components of a lock device, said lock device comprising a mechanical lock device, an electromechanical lock device or a mechatronic lock device.

2. The method according to claim 1, wherein said internal components include a movable plug.

3. The method according to claim 1, wherein said internal components include plug pins, driver pins and springs.

4. The method according to claim 1, wherein said internal components include bolt throwing elements.

5. The method according to claim 1, wherein said internal components include electrical components or a printed circuit board.

6. The method according to claim 1, wherein said hydrophobic coating is applied on the internal components after the internal components are assembled in the lock device.

7. The method according to claim 1, wherein said hydrophobic coating is applied on the internal components before the internal components are assembled in the lock device.

8. The method according to claim 1, wherein said lock device comprises a cylinder lock.

9. The method according to claim 1, wherein said lock device comprises a padlock.

10. The method according to claim 1, wherein said hydrophobic coating comprises a sol-gel coating.

11. The method according to claim 1, wherein said hydrophobic coating comprises a parylene coating.

12. The method according to claim 1, wherein said hydrophobic coating comprises a silicone compound.

13. The method according to claim 1, wherein said hydrophobic coating is applied by a chemical vapor deposition (CVD) process.

14. A device comprising an electromechanical key with a hydrophobic coating applied thereon.