NO154914B - SAFETY CRANE SAFETY DEVICE. - Google Patents

Description

The present invention relates to a safety device

for a faucet. The purpose of the invention is to provide a device which can quickly cut through a lifting rope on a crane to release a load which would otherwise be able to destroy the crane structure. There is a particular danger of this on cranes in connection with offshore platforms when the crane beam is in a completely horizontal position to load or unload supply boats that maneuver around the platform's foundation. The boat can be unexpectedly moved down in a swell so that the load is temporarily not supported, hanging at the end of the crane, until the crane beam has been moved up to its lifting position. If the lifting wire is then completely overloaded so that it breaks and the load is thrown overboard,

the faucet will not usually be damaged. However, it is not uncommon for the wire to hold and the forces that then act on the crane beam and on the crane's swivel base can cause the crane to break or even move it away from the platform.

A safety device according to the present invention comprises the following features: a) a block which has a through passage through which the rope or cable is guided when the body is in use, and which also has an internal bore opening into the through passage; b) a piston which is slidably arranged in the bore and which can be moved, when in use, alternatively to . or away from the rope; c) a rope-cutting blade carried by the piston, the blade having a cutting edge held adjacent to, but not in contact with, the rope when the piston is in its retracted non-cutting position; d) a cartridge which is placed behind the piston and which contains an explosive charge; e) a charge-detonating stick located behind and adjacent to the cartridge; f) an electrically operable device for firing the pin into the cartridge and thereby exploding the charge, driving the piston against the rope, and then causing the blade to cut the rope to release the charge.

The electrically operable device can be an electromagnetic solenoid since these have proven to be effective and are essentially problem-free, at the same time that such solenoids require relatively little electrical current to operate. The solenoids are also well suited to being arranged in an integrated arrangement with blade, piston, charge-containing cartridge, and a spark plug surrounded by the solenoid.

Alternatively, the electrically operable device may be of a type which is initially affected by electricity, but which relies on a chemical reaction to fire the fuse into the cartridge. Such a device is already known and can be incorporated into the device according to the present invention. Such a solution will likewise be as compact as, if not more compact than, solenoid arrangements, while at the same time such a solution exhibits well-proven reliability.

A safety device according to the present invention is shown in the accompanying drawing. This shows only one of many suitable embodiments. The embodiment shown is the one currently considered by the applicant to be the most suitable embodiment of the invention.

The only figure shows a cross-section through the safety device.

The figure shows a rectangular steel block in the form of two halves 11a and 11b. The block is divided vertically into said two parts, the main part 11a having a volume that is slightly more than twice the volume of the secondary part 11b. The two parts are in practice held together by means of screws which pass through channels in the secondary part 11b and which enter corresponding threaded bores in the main part 11a of the block.

The screws, channels and threaded bores are not illustrated, but the screws may have cylindrical heads with recesses for receiving an umbraco key and when the screws are fully screwed in the heads will be well below the surface of the block half 11b.

The screws that hold the block together and their cooperating bores are positioned in relation to each other in such a way that they pass on either side of two semi-circular channels 15a and 15b, which channels are formed in each of the block halves respectively 11a and 11b. When the two block halves are brought together and held together by means of the screws, the two semicircular channels 15a, 15b will together define a circular cylindrical bore which extends through the block and which runs parallel to the vertical sides of the block.

The vertical channel 15 is smooth-walled and has a diameter that is somewhat larger than the diameter of the wire 16, for which the device is intended to be used in connection with. The wire

16 can in this case be a bent steel lifting cable which is used in connection with and which forms part of a crane. The crane itself is not described or illustrated. Wire 16

has a built-in breaking point, and the safety device is intended to cut the wire in cases where the load in the wire could destroy the crane structure without the wire itself breaking.

A piston 17 slides back and forth in a bore 18 formed

in a barrel 19. The piston, the bore 18 and the barrel 19 are all in the form of a cylinder of circular cross-section. The barrel 19 is screwed into the block half 1a and extends from and forms an extension of this block half 1a when it is screwed in completely. The end of the barrel aligns with the bore 15 when the barrel is fully screwed in, as shown in the drawing.

The piston 17 has a head 17a with a smaller diameter. A blade 21 is fixed in a slot in this head 17a and extends from the head towards the rope 16. In the figure, the blade is seen from the side and it has a rectangular shape. Its cutting edge 21a may be straight or it may be semicircular or otherwise curved in the same direction as the rope 16, or even in the opposite direction. The blade 21 is fixed but removably attached by means of a pin through the head of the piston as indicated by reference numeral 14 in the drawing.

A cartridge 22 fits exactly into a bore 13 which extends from the end of the piston which has no head and towards the piston head 17a. The cartridge 22 contains an explosive charge. The end of the cartridge opposite the piston head 17a is closed and when the cartridge is stored the other end will also be closed by an end cap 22a of a relatively soft metal. The underside of the end cap 22 of a soft metal is chamfered to fit with a corresponding chamfered counterpart at the end of a bore which extends through the center of the firing chamber 23. The fit between these two chamfers prevents the cartridge 22 from sliding further down through the bore 13, which bore is longer than the cartridge in this particular case.

The firing chamber 23 contains the piston body 17. The chamber 23 is screwed inside the barrel 19. A firing chamber end cap 12 is screwed over the projecting end of the firing chamber 23. A threaded bore 24 in the end cap 12 is co-axial with the counterbore in the firing chamber and with that in the piston body located bore 13.

A detonator 25 is screwed into the bore 24 and supports a firing pin not shown in the drawing. As shown, the detonator 25 is extremely small and short. It is fired electrically and the live wires (not shown) are led out through the top of the end cap 26 into the chamber, which cap is screwed over the firing chamber 23 to surround the chamber, end cap 12, and piston 17. The end cap 26 forms a cylindrical extension of the barrel 19.

The detonator 25 is manufactured in Great Britain by Nobels Explosive Company Limited (a subsidiary of ICI plc) and

marketed under the trademark "METRON"! The detonator is known as a piston conveyor. This is a single-shot device for producing rectilinear motion, and it is operated by small electrical impulses rapidly converting latent chemical energy into rectilinear motion of a piston carrying the necessary charge-detonating firing pin. This device is energized with as little as 0.2 amps. current and when energized the firing pin will be hurled forward to break through the soft metal jacket 22a and detonate the charge inside the cartridge 22.

A cylindrical plastic sleeve 27 is heat-shrunk around the barrel 19 and barrel end cover 26 to protect the moving parts of the device from the weather. The cover 27 is heat-shrunk in place where the barrel end cover 26 is screwed in over the firing chamber 23. A collar 28 is then screwed onto the block half 1a and rests against the end of the cover 27 to deform it and to complete the watertight seal of it out from the main block towering race.

A circular plastic disk 29 is placed in a recess

in a bushing 31 which is screwed into the main block half along the threads which will afterwards receive the barrel 19. The plastic disc 29 is held in place by a ring 32 which is screwed into the bushing 31 from the half bore 15a. The disc protects the blade edge 21a against accidental unraveling of the rope 16 during normal use of the rope, i.e. when the safety device is inactive.

It also acts as a dust cover that protects the internal moving parts of the device.

An internal taper in diameter of the bushing 31 is chamfered as indicated by the reference number 33. A correspondingly matched chamfer is formed on the front end of the piston head 17a.

Channels, 34, 35 are bored through the main block half perpendicular to the common axis of the piston and the other cylindrical components extending from the block. The channels 34, 35 are located on each side of this axis. One end of each of these channels is plugged again. The other end acts as an exhaust manifold.

The bushing 31 and the barrel 19 do not bump into each other when these are screwed in fully. A gap 36 is thus provided between their adjacent surfaces.

In use, the two block halves 11a and 11b are brought together around the rope 16, these being screwed together to form a circular bore 15. The rope can freely slide up and down through said bore. The piston 17 and the blade 21 are in their retracted position as shown in the figure, while the cartridge 22, which is loaded, remains undetonated. The firing pin of the detonator 25 almost touches the soft metal end cap 22a of the cartridge 22, but has not yet cut through it. The device hangs from the head of the crane arm by means of a shackle, not illustrated, the rope 16 running vertically back and forth to raise and lower loads.

The load on the crane structure can be measured using strain gauges or other automatic devices that give the crane operator an indication of the loads in the structure. As long as these loads remain below predetermined levels, the safety device remains inactive.

If these safety levels are suddenly and dangerously exceeded and it is obvious that no immediate removal of the overburden is possible, the crane operator can use the emergency device by pressing a control button to energize the detonator 25 electrically. The detonating pin is fired through the soft metal jacket 22a and into the cartridge 22 to detonate the charge inside the cartridge. The exploding charge drives the piston 17 against the rope 16, so that the blade edge 21a is caused to cut immediately through the soft plastic sheath 29 and cut the rope 16. The rope, which is already under tension, is likely to be cut without the blade 21 necessarily having cut completely through this. Under all circumstances, the load will be released in order to save the crane.

The exploding charge will generate quite a large amount of heat inside the block, since the blade, no matter how sharp it may be, must necessarily be driven at a significant speed to achieve cutting a modern steel cable. It is assumed that the exposed position of the block up at the end of the crane arm will cause most of this heat to dissipate naturally. If this does not seem to be the case, the block can e.g. be equipped with a fin to increase the degree of heat dissipation. Alternatively, the block may be surrounded by a jacket in which a coolant circulates.

Propagation of pressure waves caused by the exploding charge must also be taken care of. The piston head 17a will, when this

is in its extreme position on the left side of the figure, uncovering the channels 34, 35 and 36 as well as effectively shutting off the previously existing communication between the bore 18 and the bore 15 via the cut disc 29. The shock wave will travel out through the channels 34 and 35 to the previously mentioned manifold. If necessary, the manifold can be positively vented to remove excess pressure.

The piston 17 may tend to rotate about its own axis. A channel, not shown, may run along a wall of the bore 18, parallel to the bore axis with a locking ball which is spring-loaded into a recess in the piston and which cooperates with the channel to stop the piston from rotating. Thereby, the blade 21 is held in its illustrated position when the piston is moved forward.

Although the blade 21 does not necessarily need to cut completely through the rope 16, this can happen under certain conditions. A piece of wood or a piece of other soft material in relation to the blade edge 21a can be placed in a recess in the block half part 11b, so that the blade edge is pressed into it. Alternatively, a slot can be arranged in the block half part 11b for receiving the blade edge, as sufficient clearance is provided around the walls of the slot so that the blade edge does not come into contact with the metal around the slot, but is simply absorbed in it.

To cut through a broken steel cable, e.g. with a diameter of 1.5 inches (about 38 mm), a pressure of 7,500 to 8,000 pounds per square inch is generated by the exploding cartridge. The "METRON" actuators DR 2003/2005 CI provide 200 to 300 kg force-cm. in original impact and has a working time of only 15 m/s. The working stroke of these actuators is between 3.5 to 10 mm, and unpublished experiments have used a standard "ELY" clay pigeon cartridge to generate the explosive piston driving force.

The outer surfaces of the block 11 and the runners 19, 26 are painted with the usual accepted contrasting colors to indicate a safety device.

Faucets of the type with which the illustrated device is intended to be used are already equipped with a limit switch. The block 11 may constitute a standard limit switch weight, modified as described and illustrated to take the remaining components of the safety device.

Claims (5)

1. safety device for cutting a load-lifting rope or cable in the event of an overload, characterized by the following combination of features: a) a block (11) having a through passage (15) through which the rope or cable (16) is guided when the body is in use, and which also has an internal bore (18) which opens into the through passage (15); b) a piston (17) which is slidably arranged in the bore (18) and which can be moved, when in use, alternatively towards or away from the rope (16); c) a rope-cutting blade (21) carried by the piston (17), the blade having a cutting edge (21a) which is held adjacent to, but not in contact with, the rope (16) when the piston (17) is in its retracted non-cutting position; d) a cartridge (22) which is placed behind the piston (17) and which contains an explosive charge; e) a charge-detonating pin located behind and adjacent to the cartridge (22); <f>) an electrically operable device (25) for firing the pin into the cartridge and thereby exploding the charge, driving the piston against the rope, and causing that the blade cuts the rope to thereby release the load. 2. Device according to claim 1, characterized in that the electrically operable device (25) comprises an electromagnetic solenoid. 3. Device as stated in claim 1, characterized in that the electrically operable device (25) comprises an electrically actuable piston detonator of a type that uses a chemical reaction to fire the stick into the cartridge (22). 4. Device as stated in any of the above-mentioned claims, characterized in that the blade (21) is removably arranged by means of a pin (14) situated in the head of the piston (17). 5. Device as set forth in any of the preceding claims, characterized in that passages (34, 35, 36) provide communication between the interior (18) of the block (11) with the outside atmosphere, said passages allowing the pressure wave, generated of the detonation of the cartridge (22), to dissipate.