PL6975B1 - Automatic device, announcing break-ins, fires, as well as securing cash registers, vaults and the floor of the room. - Google Patents

Description

The essence of the present invention are devices indicating break-ins or fires, as well as devices for closing, securing and protecting cash registers, vaults, and mainly the invention is intended for the protection of houses, buildings, and households, only certain parts of such rooms. The security features encompassed by this invention go far beyond triggering an alarm when unallocated hands are touched on the object to be protected. The methods listed below may capture or imprison the perpetrator of an attack. The invention can be adapted to carry out all or some of the indicated activities, and is entirely suitable for introducing into its scope of operation other methods of securing rooms, objects or persons not covered by this description. of the invention for strongboxes, the locking and unlocking of doors and windows, as well as for the closure of armored bank boxes, since the principle of each device may find extensive application in many other cases not mentioned. cash registers, equipped with special walls with empty sections between them, which will appear in the following description under the general name of "chambers", and with means announcing the automatic break-in or outbreak of fire, which can effect the prevention of pressure-sensitive devices also with temperature changes The mentioned pressures arise at a greater or lesser rate The invention also provides a means of making it impossible to open the lock using less pressure than required by the lock device. Under the term pressure, one should understand the efforts coming from all sources, not excluding the vaouum and electric current. A characteristic feature of this invention is the peculiarly arranged locking bolts of two basic types: bolts (provided with a gripping device and means for releasing and releasing pressure, and bolts) , also having gripping devices and pressure-active devices derived from a special bolt. These devices are provided with particularly designed lock parts; latches and a pressure motor to release these latches; the interlocking device b also has an alarm device that operates under action pressure from the tubes connected to the cash register, and a cork of fusible material, which remains under the pressure of the water in the tubes and melts when the temperature is raised, thereby releasing the trapped water in the tubes so that the water is forced to circulate in the tubes. inter-wall chambers, while the door of the cash register is cooled down and the risk of fire propagation is removed. The attached drawings show the cash box made as a cabinet with a wall between which there are two independent pressurized chambers, I have provided for some reason. The door of the cash register has a similar structure and their walls are also formed by two chambers, which from time to time are subjected to the effect of pressure reaching the chambers by means of special bolts. Each cash register may contain one or several chambers. It should be noted that each of the chambers is subjected to pressure separately by an independent conduit, which, when extending outside the chamber, connects with the tube also independent, so that the cash register and door chambers form a kind of sections in which the pressure circulation takes place. . This pressure is governed by either a reduction valve or a self-positioning of the inlet, or both, simultaneously, ensuring that the entire system is kept at a uniform, constant pressure, spring-balanced or other method; the violation of this balance causes the suspension or circulation of the electric current in the network or causes other desired actions to protect the entire cash register. The entire system of chambers supplied to them from an external source of pressure has two main points: a first feed inlet and a second interfering outlet. The latter, as already indicated above, is provided with a spring or other device which senses any changes in pressure, deforms under the influence of these changes, and affects alarm devices or other safety devices. Thus, if in any section of the ventricular array a change in the starting and remaining pressures of the system is induced, then this change produces an identical change at the active end point of the system. The changes, therefore, or in fact the colder drop in the initial pressure, may be caused by making a hole in the wall of the chambers, damage to the feed tube, etc., and then it is obvious that the equilibrium of the spring pressure adjusted at the point end of the circuit is broken and the device starts to operate. In addition to the above-mentioned reasons, the imbalance also causes a temporary opening and closing of the cash register, as well as the insertion of any tool into the pipes and the isolation of the tubes. In order to disturb the system equilibrium due to the permissible external temperature changes, the sensitivity of the device can be destroyed within these limits by adjusting the pressure source properly, as well as by using a thermostatic pressure regulator which acts as a lever by means of a lever rod on the reduction valve and the reduction valve. The imbalance of the pressure system occurs simultaneously in all the chambers, if there are changes in the pressure in the main reservoir. The source of the pressure, the strength of the melting plug, the setting of the reducing valve and the spring, as well as the causes of the system imbalance, can be changed in any way and can be used all at once or abundantly and in large numbers. To prevent pressure reversal, it is recommended to set check valves in the system that prevent pressure from returning to the pressure relief valve and permeating it, as this valve protects the efficiency of the entire device, as well as check valves prevent pressure from penetrating through the connecting plugs The aforementioned valves, with a pressure adjusted before entering the system, cause that any increase in pressure caused by the inclusion of a power source in any pin or part of the cash register will cause the equilibrium spring to act and therefore cause an alarm. . Alarm diving lines can connect parts of the system that connect to the pressure lines or the compressor cylinder. Generally, alarm tubes should be connected to that part of the system that appears to be most exposed to rapid, sharp changes in pressure when the warning action is performed. Obvious; The advantage of this combined pressure with electrical closing and unblocking methods over other electrical systems hitherto in use is that open electrical circuits are necessary to safeguard the efficiency of the given system, while closed circuits are used in cases where The system is connected to the system (telephones or microphones are used. With the analogous use of a given telephone system, a closed current is necessary, but then the influence of this current is eliminated at the expense of an open circuit of the current, closed at each contact with the coil. The fact that the action of this current is actually removed shows the fact that so far it is not possible to determine the voltage generated at the closing point. The ammeter in this case will not be as useful as the use of special cables, The fluctuating pressure fluctuations in the system should be counteracted by the resistance of the tubular lines by attempting to maintain steady equilibrium. For the implementation of the arrangement, in addition to known materials, it is recommended to use cement reinforced with bandages made of hardened steel, glass, porcelain, earthenware, rubber; These materials, or their combination, ensure that it is impossible to damage the object without a drop in pressure, and that a change in pressure will inevitably trigger an alarm. As a rule of thumb, when selecting the material, it should be taken into account that while tapping or drilling the cash register it was impossible to maintain a balance of pressures. Only the drilling and striking of the alarm lines can be destroyed, but the coup d'état may only be effective in the case of such actions, in which it is not restricted at any point. the openings of the wires, nor will the stiff or flexible rubber partitions be damaged, or the% of the combined material - they protect the last part of the cash from damage and tearing by a person due to an attack on the cash box, because with such damage the alarm signal becomes active. The above principle can be successfully used to protect the watertight sections of the ship in the event of a breakthrough threatening to destroy the positive buoyancy of the ship. The spindles of the hinged kaisy door may be empty with a hole on the inner edge connected to the pressure chamber. The spindles destroy the balance of the system. This device can be operated with vacuum and electric current. When the door of the cash register is locked, the rotation of the adjusting wheel placed outside the cash register opens the cocks connecting the chambers of the cash register with the chambers of the door, then the pressure in all chambers of the cash register and In addition, a certain number of small spring or diaphragm bolts in the chambers of the door, weakens it from the main chambers when the pressure balance has been established, In the event of a fire breakout in the bottom of the cash register, the stopper is melted in the special tubes pressure; water begins to circulate in the chambers and protects the cash from excessive heating. When a different pressure is used instead of the water pressure for the above purpose, the water released by the melting of the stopper may undergo its cooling circuit, being carried away by the pressure used. Thus, any means of removing heat build-up may be employed. Pressure tubes may be used as telephone lines, and senders and receivers may be microphones and resonators. The combination of these systems guarantees constant signaling performance. The microphones can be attached to empty conductors. At the end of the system, to announce a loud sound, with any swing, the entire cash register is included. The above description covers all the means of the cash register securing device according to the main principles of the invention and one of the two existing combinations of locks. If burglars try to get to the cache with the help of the tools introduced into it, the bombs explode inside the cash register, destroying the tool without any harm to the cash register, at the same time the violation of the pressure balance in the chambers causes alarm signals. The door pivot and latch, keeping the bolts closed, protrudes from the toothed wheel, pulsating the bolts aside and breaking the pressure communication at the same time. However, the pressure in the door chambers remains and the spring bolts are completely obscured. Detailing the details of a given invention and ways to implement it h rules. 1 shows the perspective view of the cash register with sectional sections, the door of which is open; The figure shows the pressure regulator, rising tooth and the like. 2 - perspective view of the closed cash register; Fig. 3 is a vertical section of the chambers of the door and the wardrobe showing the device of the pressure actuated mechanism, the through bolts and the device for lifting the pusher; the cross-section of the diaphragm bolt is also shown; Fig. 4 —- horizontal section of the door and wardrobe chambers, showing the mechanism in relation to the tab lifting device, and the arrangement of the bomb curtains; 5 is a detailed sectional view and a diaphragm view of the bolt with spring; - 4 —fig. 6, similar to 'fig. 5, shows only vacuum; fig, '! ¦ — Przekiróij vaicuuim with bolt and spring; Fig. 8 is a fork in section of the cabinet door and chambers showing the distribution of the reducing valves and the device under pressure at the time of alarm; Fig. 9 is a section of a detail of a through bolt and a bolt valve; Fig. 10 is the same as Fig. 9, but showing the device in a closed state; Fig. 11 is a horizontal section of the compressor and the arrangement of the unlocking bolt; Fig. 11a is a detail section of the pin of the lifting pin; Fig. 2 shows the perspective of the closure of the pressure relief; Fig. 13 is a section of the door showing a side view of the pressure-operated closure; Fig. 14 is a perspective view of the inside of the alarm device housing; Fig. 15 is a sectional view of a particular alarm device; Fig. 16 is a sectional and side view of a pressure gauge of an alarm device; Fig. 17 is a side view of the battery compartment housing; Fig. 18 is a view of the slope and a partially sectioned view of a spring-loaded water-fluid alarm device actuated by the discharge energy. Fig. 19 is a slope view and a partially sectioned view of the chart device; Fig. 20 is a sectional view of the pressure operated bolts; Fig. 21 is a slope and partially sectional view of the electrical contacts of the alarm device; Fig. 22 is a schematic diagram of the electrical contacts and alarm network; Fig. 23 is a view of the closing slope of the device as applied to a single door; Fig. 24 ¦ is a detail view of a closing device for a door; Fig. 25 is a side view of Fig. 24 showing the layout of the pipes and valves; Fig. 26 is a front view of the window grille; Fig. 27 is a sectional view of the explosive cell; 28 is a cross-sectional view of bank windows with an indication of the layout of bank box securing devices; Fig. 29 is a cross-section similar to Fig. 28 showing the layout of automatic closures and safety devices as applied to bank windows; Fig. 30 is a front view and a cross-section of Figures 28 and 29. Application of the invention to a double-chamber cash register (see Fig. 1). The walls 2 and 4 are kept at a distance from the central wall 3 by means of spacers 5, placed at a distance from each other. These walls form the chambers 6 and 7. The wardrobe is provided with a door S having chambers 9 and 10 and suspended by hinges 11 (FIGS. 1 and 2). The door 8 has a bolt 12 (Fig. 3), described in detail below, and is operated by a special device consisting of coils and screens mounted on the spindle 13 and through chambers 9 and 10 (Figs. 3 and 4). ). Then the door on May 8, walls 14 and 15 supported in points 16; The door is actuated by a handle wheel 17. It is closed in the usual way (Fig. 2), and a special bolt 12, by means of the device described above, slides upwards and still falls into the cranks embossed in the outer walls of the cabinet. The door 8 is provided with a number of spring bolts 18 (Fig. 315) located around the four sides of each chamber and acts in the manner given below, # - 5 The pressure to chambers 6 and 7 is adjusted! In the following manner: The pressure tube 19 is provided with a shawl and a tap i9a and penetrates through chambers 6 and 7 (Jo of the interior of the cabinet 1. From the tube / 9 through the shut-off valve 20 and the number J9 & the pressure will enter the chamber 6, a Chamber 7 receives the drain from the same tube J9 through the tube 21, the pressure reducing valve 22 and the tube 2 / a; from na Aai 19 the pressure, penetrating through the tubes 23 and tube 24, penetrates into the compressor 25 (Figs. 1 and 8 ), Each of the chambers 6 and 7 is independently connected to the alarm devices 26 and 26a by means of pipes 27 and 27cr. Details of the closing ends of figures and 12 (Fig. 3 | on the prefloat 1 Komoraicfi are shown in Figs. 9 and 10. Kon The ec29 of the bolt 12 is provided with a bolt muff 30, containing a suitable spring '31, cut between the valve guide (fixed inside the sleeve 30) and the end 29 of the bolt 12. The stem 33 of the valve passes through the point of the joint 30, springs 31 and guide 32, the end of the bolt $ 9 is screwed on; because of the springs 31 , the head 34 of the bolt falls into the socket 35, placed in the end of the mttfy 30. The end of the muffle 30 fits in the sealing box 36. that rests on the Wall 37 of the door 8. The opposite end of the muffle 30 passes through the cylinder 28 in the Chamber 6. In the cylinder 28 are placed piston 38 and spring 39. The bore 40 in the end of cylinder 28 is arranged such that the piston 38 can fit snugly against the walls of the seat 41. and the end of the muffle 30 against the walls 42 of the seat. When closing the bolt 12 (Fig. '91, the end of the bolt 29 and the muffle 30 advance towards the chambers 6, being moved by the coils and the stopper wheel 17 fFig * 4). The end 29 of the bolt (FIG. 9) and the end of the sleeve 30 move simultaneously against the resistance of the spring 31; at the same time, the clone of the muffle 30 rests against the seat 42 of the opening 40, and the bolt 12 continues to advance as the rod 17 continues to rotate and continues to compress the spring between End 29cr and guide 32 until it engages in seat 42. At this point the head 34 the valve is pressed by piston 38 and spring 39, opening the outlet 43 and merging into one outlet 44 and 45 (Fig. 10). These movements allow the transfer of pressure from Chamber 6 through passages 43, center & K End of muff 30 and flights 44 and 45 to the Chamber 10 doors 8 so far, until the pressure in the chamber is equal to the wardrobes and the door. In this way, in the chamber 10 of the door 8, the pressure is "introduced by spring or diaphragm bolts 18 (Figs. 3 and 5) to the sleeves 46 of the wall 3a (Fig. 11. The bolt offset 12 is described below, they are cut apart) aids to move the STEERING BACK 17. Under the action of the spring 3 / the end of the sleeve 30 holds and remains in the seat 42 until now, until the valve head 34 is not plunged into the seat 41, the ports 43 will be closed and the openings 44 and 45 When the position of the pressure system parts in kbmóracli 10 and 6 are separated, the Chamber 10 is separated from the source and the bolts 18 remain closed. Further, moving the bolts 12 causes the end of the muffle 30 to move away from the source. 40 until the play between the walls 3a and 37 is exposed. The action of the spring 31, the head 34 holds the slings firmly in the seat 35. The spring 39 is under pressure from the passage 47 in the slot 41. All bolts 12 are operative according to the above-mentioned method and nests These valve bolts and valve heads must be properly aligned. Bolts 12 are pushed in and out with the movement of Wheels 48 (fi *?. 3 and 4), coupled to the ends 49 of the bolt 12. The pinion 48 is loose on the shank 13 and moves when turning the modes 50, 51, 52 and 53, which can be set in the wrong position and fastened with pinion wheels 53 , attached to it; to the spindle 13, rotated by the wheel 17, the spindle 13 is pressure-sealed by a throttle 54, - 6 - which can be freely adjusted, A brake wheel 55 in the chamber 9 is mounted on the shaft 13 (Figs. 3 and 4), 60 falls between the prongs of the wheel 55 so that the bolts 12 can always be pushed outwards towards the socket 28, but the reverse movement of these bolts is only possible when the bar 60 is released with the ring 55. The method of this release is given below. A compressor 61 is located inside door 8 (figures 1, 3 and 4); It consists of a cylinder 62 provided with a piston 63 attached to a cable 64 to a movable pulley 65. The compressor is provided with a tube 66 and a valve 67. The spindle 68 moves in the compressor, penetrating the boss 69. This spindle is provided with the reference. a forged movable wheel 65, mounted loosely on it and connected to it by a cable 64 and a pin 70. The gear wheel 71 is wedged on the spindle and stops the pin 70 so attached to the wheel 65 and 71 that the movement of the wheel 65 from left to right turns the spindle No. 68, and the movement of the wheel in the opposite direction of the spindle does not rotate. The spindle 68 penetrates into the chamber 9 of the door 8 and is provided with an eccentric disc 72, bent over it in such a position relative to the rod 73 that its rotation releases the tab 60 from engaging with the wheel 55, and then rotation causes it to reconnect. A spring 74 is attached to the side of the wheel 65 facing away from the compressor. The tube 66 passes from the inside of the door 8 through the chambers 9 and 10 to the outside and is provided with a valve 66c. The compressor releases the closing tab 60 as follows. cylinder 52 through the inlet port 75 acts on the surfaces of the piston 63 and forces the piston to the bottom 62a of the cylinder when valves 66a and 67 are open. Pushing over the bottom of the piston 63 causes the pulley 65 to turn with the help of the cable 64. This movement, from left to right, leaving the tooth 70 in engagement with the gear 71, turns the spindle 68 and the eccentric 72 When the shorter radius of the eccentric 72 reaches on the line with the bar 73, the claw 68 is released from the mode, thereby allowing the spindle 13 to act on the pulley 17 and moving the bolt 12 away. When the eccentric 72 returns to the position indicated in Fig. 3, the claw 60 is re-engaged with during this movement of the piston to the bottom of the cylinder 62a, the spring 74 is under pressure. When the valve 66a is closed to release pressure, the piston 63 allows the pressure to accumulate beneath its lower surface and when the pressure is balanced, the spring energy 74 causes the right-left movement of the wheel 65 by advancing through the piston 63 towards the top of the cylinder 62a and twisting the cable 64. This rotation of the wheel 65 does not cause the spindle 68 to rotate, and therefore does not change the position of the eccentric 72 in way back. A certain drop in pressure must occur before the bolts 12 are moved; this fall upsets the balance of the system and causes alarm signals, causing the network to close the current circuit. There are some variations of this device and it can be used for other activities caused by the release of the braking stick. Figures 24 and 25 give a variation in that the tooth remains off as long as the pressure drops or the outlet remains open, and the piston's own weight causes it to travel back. The compressor 61 raises the tab 60 while the pressure accumulated under the piston 63 can escape through the valve 67, tube 66 and valve 67a. However, as the valve 67 is inside and valve 66a is outside of door 8, the pressure cannot cause the above action when opening valve 66a while valve 67 remains closed. - 7 - The valve 67 is opened as follows. Pressure is applied to the reservoir 25 (FIGS. 1 and 8) through a valve 23 regulating the amount of inlet and through a tube 24 connected to the main supply line 19. The tube 24 is provided with valves 75 connected to the accumulators. the pressure 76, located in the chambers 6 and 7. These accumulators may, if necessary, be isolated in the sleeves 24 by means of valves 75 or connected to them. Their task is to pressurize the spaces which are to remain under pressure in succession. there are transverse rods 78 and 78a which open the valve 67 of the compressor pressure circuit and the valve 79 of the tube 80 when final pressure has accumulated in the reservoir 25. In the lower right part, the reservoir 25 is provided with an outlet valve 81 and a discharge tube 82. through the walls of the cash register, the needle of the valve 81 is firmly closed by door 8, and when the door is opened, the pressure exits outward through the tube 82. The spring 83 now moves the piston 84 to the bottom of the chamber 85. When this happens steel, the bars 78 and 78a, as they descend, allow the spring (not shown in the figure) to close valves 67 and 79. Then the degree of pressure build-up is regulated by valve 23. Tubes 86, valve 87, despite the spring 88 and the discs 89 and 89a are component parts of the device that regulates the eccentric 88 and protects the alarm system. For this purpose, the diver 86 connects the pressure of the tube 19 with an initial pressure regulator at the end pressure regulator with a pressure reducing valve 19b, and at some point (a point beyond the regulator at the valve 20. Eccentric 88 it can be turned in a suitable manner (not shown) and is so attached to the spring-loaded valve 87 that the latter opens and closes when it is rotated; Should the pressure in pipe 19 be significant? higher than in tube 19b, and therefore, when the spring valve is open, the high pressure stream is transferred to the low pressure, causing a heart rate phenomenon which causes the equilibrium spring to act and distant alarm signals. The disc 89 narrows the passage supplying pressure to the system (by means of the pressure reducing valve 20), and the disc 80 narrows the lumen of the tube 19b so that the high pressure supplied by the valve 87 should not escape through the valve 20, but the path will be directed. alarm tubes and set off a heart rate, causing the alarm. Reducing valves 20 and 22 are provided with tubes 90 for the pressure relief passage connected to a spline tube 82 which may not be used as a general spline tube; it should be placed outside in a suitable place. It should be stated that any separation of it is to cause the accumulation of the contained pressure in the reduction valves, disturbing the balance of the system and thus causing an alarm. The chambers 9 and 10 of the door 8 are provided with diaphragm bolts (Fig. 1 and 5), these bolts remain in the closed position under pressure and move away when the pressure is compromised by: (a) the action of the spring, (b) by vacuum operation when the system is active under pressure, or (c) by pressure, when the system is active with a vaouum, if used. Diaphragm bolt 18 (fig. 6) is intended for vacuum release and consists of a socket 91 made of a suitable material and attached to it ^ half-center bolt 92. These bolts are attached to the inner wall 93 of the door with moles or logs 94, passing through ring 95 of socket 91 and spreader 96 to wall 93. Pin 92 is located in recess 97 of wall 93, which is a continuation of recess 46 of wall 3a. The allowable oscillation of the socket sheath 91 ties to allow the bolt 92 to be advanced from inclusion 46 when the pressure is applied to the door chambers 8 through the through bolts 12. When the bolt 12 is absorbed, the door is isolated from the source of pressure, but remains constantly under pressure, the bolt 92 is moved away by opening the valve 99 (Fig. 2) and the resulting suction produces the yacuium necessary to open the bolts. After a while, the suction cannot in the chambers 9 and 10 by the valve 99 before the pressure in the reservoir 25 causes the opening of the valve 79 in the tube 80. The lifting of the ratchet cover may be effected by means of a second compressor whose pin is to be placed inside the chamber. The tongue of the second compressor should be arranged so that the pressure is maintained, it is released very slowly so that a considerable period of time passes after the plug is opened before the accidental tooth lifts. the fallout of the doorway before the play is exposed by through bolts. If, before the play is exposed, the pawl tab remains engaged with its mode, it is impossible to release it when the pressure is cut from the door. This danger can be eliminated in several ways, for example: (a) and by fitting the bolt with an axial pin and a non-ratchet mechanism, (b) by applying a sensitive power supply to the compressor from the chamber, and (c) by a device, gears and a braking gear Wheels made of tern, so that this mechanism is not coupled with the brake wheel, in which the pawl of the ratchet may be stuck after cutting off the pressure from the two pins. In the system, appropriate valves or screens may be placed here and there to prevent penetration into the interior of the system pollution, which may * affect the efficiency of safety devices; the admission of gases or corrosive liquids into the equipment should also be avoided. The diaphragm bolt 18 (Fig. 5) is intended to release the spring. Its structure and method of attachment are similar to Fig. 6, except that the crucible 92 is not attached to the sheath 91 and is provided with a spring 100 which causes it to expose two walls when the pressure is contained in it. the door chambers are released. The pressure bolt 101 (Fig. 20) is intended to release the spring and consists of a cylinder 102 which is tilted to the wall 93 by moles or staves 103 and provided with a piston 104, a spindle 105 of a spring 100 and bolt 92. Pressure is applied to the plunger through port 106 and its operation is similar to that shown in Fig. 5. Pressure bolt 106 (Fig. 7) is closed at vaouum and open at pressure and consists of box 107, opening 108 for vacuium, inlet opening 109 for atmospheric pressure of pneumatic device 110 and diaphragm 111. Box 107 is attached to the wall 93 of the door, and the bolt 92 to diaphragm 111 to be positioned behind speed when the pneumatic device HO (attached to the bridge 111) collapses under the action of the vacuum generated by the holes 108. The edges 112 of the pneumatic 110 are fixed to the wall 93. When the door bolts are connected to the wardrobe chambers, is obtained through the chambers of the door by the exception of the box 107 which is connected to the atmosphere. When the pressure in the air bags 100 becomes less than the atmospheric pressure, the latter forces the pneumatics to collapse, causing the diaphragm of the lila to collapse, and then the bolt 92 will be placed in the closed position. . a_ 9 —When the door is cut off by vacuum by moving the through-bolts for the vanum, and atmospheric pressure is released by the valve 99 (Fig. 2), the apreset 109 forces the bolt 92 to expose the slack in the walls. Figures 11 and 11 show a certain variation of the closing device: a cashbox opening. The spindle 13 has the purpose mentioned above, but because of the additional device, the handwheel 17 described below can only be used to bring the bolts 12 to the closed position and cannot be used to push them back. In the door chamber 10, the compressor 113 is set. Pressure is alternately applied to one end 114 of the cylinder to the other 114a, and the index is also effective sequentially through the outlets 115 and 115a; The device has dv / a two-way spring valves 116 and 116a, tubes 117 and 117a, and spout tubes 125 and 125a. The piston 118 should travel back and forth, with the movement of the piston through the tudbu elements 120 and 121 causing the movement of the crankshaft 119. The operation of the compressor is controlled from outside the door by observing the movement of the buttons 124 and 124a moving in the cavity. at the end of the piston stroke. The crankshaft 119 is provided with a coil 122 coupled to a gear wheel 123 which, by means of a suitable gear, connects coil 53a to the end of sleeve 126 and turns it only in the direction of bolt release 12 when compressor 123 is active. The coil 53a is loosely mounted on the spindle 13, but is thus rotated by the spindle towards the lock of the bolts 12; this movement takes place via the clutch 127 (wedged on the spindle 13). When the wheel 17 is turned towards the closure of the cash register, the gear 127 engages with the coil 122, whereby the gear transmits the rotation force to the bolt 72 closing turn using toothed wheels 52, 51, 50 and 48; but when the wheel is turned in the opposite direction, coupling 127 indie interlocks with the coil 5J, therefore the bolt cannot be moved away with this movement. The compressor and the device described above must be constructed in such a way that the opening and closing of the bolt can be carried out without intervention wheels 17. In addition, an auxiliary threaded bolt with a separate spindle and a device for pressure supply to the chambers should be used! or another method of applying pressure must be used. The closing or closing devices are to be actuated as follows: and in Fig. 12 the numbers 128 and 128a are the cylinders, the corresponding pistons are given by 129, 130 are the springs, 131 and 131a are the piston rods, 132 and 32a are the closing ends of the piston rods. ków 131 and 131a. 3a is the thickness of the cash register material, 133 and 133a are the lines supplying the pressure of cylinders 128 and 128a, 37 * the thickness of the door material. Numbers 134 and 134a denote straight-through regulating valves, 135 is a suction pump, 136 - alarm tubular lines, 137 and 137a - actuators of active valves 134 and 134a, 138 - cover of round bolts 132 and 132a, 139 and 139a - openings in cash register wall 3a for bolt ends 132 and 132a, 140 and 140a - sleeves in walls 37 doors for bolt ends 132 and 132a, 141 - partition disc, 142 - support for disc 141, 143, 144, 145, 146 - grooves in the ends of the transoms 132 and 132a, 147 and 148 - elevations in these transoms. When the buttons 137 and 137a are in the extended position, the cylinders 128 and 128a are pressurized while the buttons are depressed - and the cylinder pressure is removed and they are open to the suction pump 135. Cavities 143f 144, the elevation 147 at the end of the bolt 132a are so positioned in relation to the depths 145 and 146 and the elevation of the end of the piston 132 and the partition 141 that {this partition prevents the same tearing of the dam and the return of the ends of the bolts 132 and 132a, when * elevations 147 and 148 cannot simultaneously pass under compartment 141. On the sliding bolts in FIG. 12, the button 137a is shown pressed in, with the cylinder 128 being cut from the pressure and the suction tube 135 open, so that the spring forces the piston 129 away. ¬ nac bolt 132a. The recess 145 at the end of the bolt 132 is deep enough to support the end 141a of the divider 141 to climb up the elevation 147 so that the bolt 132a is free to move away, but if there is an attempt to move bolt 132 away, the recess 143 in bolt 132a is not quite deep to allow end 141a of partition 141 to climb up elevations 148, this attempt ends with pinching of both bolts. When bolt 132a is fully extended, recess 144 is in line with gate 141 and is quite low to allow end 141a to climb elevation 148 and when the button is depressed, the bolt J32 may be moved open by the action of the piston 129. The button 137a should be deeply countersunk during this operation. When the bolts 132 and 132a are fully extended and the buttons 137 and 137a are released, an attempt to bring both bolts into the latch position at the same time will do nothing if the elevations 147 and 148 have not previously been brought in contact with the compartment 141. bolts 132 and 132a are closed, button 137a is pressed in, thereby relieving pressure from cylinder 128a and pressure on ridge 147 exerted by end of baffle 141a which allows piston 129 to displace bolt 132, forcing baffle end 141b to climb up ramp 148 so far as long as the end of the bolt is seated in the seat 140 (Fig. 12). Now, when the button 137a is released, pressure is applied to the cylinder 128a to displace the bolt 132a - the free end 141a of the baffle steps up and the elevation 147 and extends the end of the bolt 132a to seat J40a. can move away from their seats due to the simultaneous convergence of elevations 147 and 148 towards partition 141. There are many other ways of applying this principle to the locking and unlocking of a bolt, based on the ground, so that the bolts have different protrusions and depressions along their length, which could hook the compartment 141. The distribution of these inequalities can be varied and arranged in any number of variations; The implementation of a simple pressure lock combination is shown in Fig * 13, where 61a is the bottom of the cylinder of the compressor 61; 66 is a discharge pump; 67 is the main valve of the entire device. Two-port valves 1499, 149a, 149b, 149c, 149d, 149e are located on line 66 and are connected to single valves 151, 151a, 151b, 15tc, 151d, 151e by means of pipes 150a, 150b, 150c, 150d, 150e, valves and the single 151, 151a and td are connected to the suction pump 152. Valve 149b is positioned to anticipate any further pressure drop and direct it along the ISOb tube towards valve 151b which allows pressure to escape to the atmosphere via line 152. 149-149e on the inside of the cash register door indicates which of the external valves 151-15le is to be able to escape pressure, allow the compressor to be placed under pressure and lift the closing closure. Tubes 150-150e are perforated inside door chamber 153 such that operation with one of these external valves will trigger an alarm. The openings 153 must be dimensioned such that the pressure release does not interfere with the operation of the compressor 61 if only one of these valves 151-151e is active. In fact, when two or more valves are open simultaneously, the pressure relief should be so large that half the overall pressure drop to - 11th degree compressor becomes impossible to operate. The general principles of an alarm system are First of all, it should be repeated with the cap that the pressure is regulated before it is brought to the secured object and this regulated pressure moves all the wires and their branches. The system of alarm devices is divided into groups, three of which are quoted below. . 15 and 17 show how the alarm device can be pressure-protected. The pressure enters the box 154 (FIG. 17) through the tube 27a, remains in the chamber and is fed into the door chamber through the through bolt 12 and exits through tube 155.Dtf The doors 156 are fitted with diaphragm and name bolts 18 and the flashing has a closing tab with the corresponding device described above. The housing 154 serves to house the battery, conduits 157, 157a, in which pressure passes into the tube 155 and is there from there as intended. Tubes 155, being directly associated with chamber 154, when door 156 is closed and the through bolt 12 is closed, there are both pressurized tubes and chamber 154. The methods for constructing the alarm device are given below. 155 is flanged and threaded with a thread 158. Inside it is a piston 759 to which a sleeve 160 is attached. The sleeve is wrapped by a spring 76f, the lower end of which rests against the piston 159. The adapted device 162 has guides 163 and The '164, in turn, is inserted into the end 155a of the tube 155 and secured therein in an appropriate manner. The end of the tube 155 is a casing 156 which has one or more sections and attaches the thread tube 155 to the thread 158. A regulated pressure acts on the piston 159, thereby pressing the spring 161 against conductor 163 and keeping the spring in balance. The end of the sleeve 160 works simultaneously with the piston 159 through the center of the device 162. The display 165 allows the insertion of a contact compartment around the center of it / 66. On both sides above and below the compartment are contacts 167 and 168, attached to the outer periphery of part 162. Both contacts are slotted with cable 157a through line 169. Contact 167 is attached to contact 166 so that each pressure build-up in the tube 155 should connect these contacts under the action of piston 159. Contact 168 is in such relation to contact 166 that any drop in pressure in tube 155 will cause piston 159 to descend, bringing the contacts 166 and 168 together. Both of these contacts are inserted into the alarm network. Wherever end 155a of tube 155 faces, it may again be enclosed in housing 156 containing the body of the alarm device. The casing is made up of a water chamber 170 in total, surrounded by a second chamber 171 which may be filled with gas or some other inconvenience to burglars. Such material is to be inserted through an opening, plugged with a suitable tailstock. When the housing 156 is screwed to the end of the tube 155, the openings 173 and 174 merge into one and the pressure is distributed evenly in the tube 155 and the adjacent chamber. it is in a separate contact 175, connected to the cable 158; the inner wall 176 of the housing 156 also has a separate contact 177 connecting by wire 176 to the cable 157. When screwing the end of the tube 155a into the housing 756, the wires must be disconnected from the battery in housing 154. Contacts 175 and 177 go at the beginning together and then in the housing 156 each in its correct place is attached, so contact 175 is above contact 777, and the wires can be connected to battery 154 and it is impossible to shift the housing 156, because it is The casing 156 is provided with an outlet tube 779 / preventing backpressure on the piston 159. The contacts thus arranged can serve for the operation of bells, making an explosion or causing other activities involved in By the signaling concept, the contact divider 166 is suspended between contacts 167 and 168, it has a thread 180 for the use of a micrometer, while the thread regulates the voltage. e reduction valve springs 120 ^ 122 (Fig. 1-8). Explosive devices belong to this type of devices, and therefore two networks should be arranged, a bell and an explosion completely independent of each other. 16 gives an example of a simple pressure balance. Regulated pressure is applied to the tube 27 system, it enters the throttle 180, provided with the tube 181 with a small spline 182 at the end. The pressure gauge 180 has a pressure gauge 183 attached to it with two separate cable clamps 184 and 184a. . These terminals are connected by wires 185 and 185a and wire 186 which are connected to the battery terminal. The spindle 187 is connected by a conductor 188 to the second contact of the battery, and the entire network is completed by the contact of the rods 189 with points 190 i) 190a. After this cycle, a current is to flow causing alarm signals. 13 gives another type of alarm device based on the extraction of the weight of the discharged water to trigger the alarm. Pressurized water or liquid is fed through a tube 27 into a cylinder 191 which has a thread 192 with a spring 193, a screw-on head 194, an outlet opening 195, and a drain tube 196. Directly under this tube and the spring 198 rests on the reservoir 197. The reservoir 197 has an outlet valve 199 on one side and an electrical contact with the drill, this contact is located in the center between contacts 201 and 202 connected to clamp 203. Contact 200 with conductor 205 connects to terminal 204 The pressure applied to the tube 27 under the piston 192 allows this piston to pressurize the spring 193 thereby pressing the head 194. The head is held in a given position by the flat spring 206. Thus, the volume of fluid discharged through the outlet 195 may be arbitrary. adjustable. The valve 199 is positioned so that the amount of fluid passed through it equals the amount of fluid passed through the outlet 195 and remains constant. The position of the reservoir 197, and hence the contact 200, is determined by the weight of the reservoir and its contents, and therefore its position in the supposition that the outlet from the tank is permanent is also steel; as spout through tongue 195 changes, reservoir 197 becomes lighter and rises, causing contacts 200 and 201 to contact; otherwise, contact 200 connects to contact 202, since this movement will in both cases generate alarm signals. If the pressure under piston 192 increases, the piston moves towards spring 193, thereby increasing the clearance of outlet 195; otherwise, the piston exits and covers the outlet 195. The tube 207 is designed to vent the pressure accumulated in the cylinder 191 above the piston 192. 19 shows a method of making a pressure variation diagram in the system. 209 and 209a are branches of the alarm tubes 27 and 27a, independently connecting the two cash register chambers to cylinders 210 and 2, 10a, and the pressure forces the pistons 213 and 213d to counter the springs 212 and 212a. The elongated doors of both pistons have blades 214 and 214a at their ends. With sufficient pressure on the pistons, the piston rods rise from the cylinders 210 and L10a, without letting it bend: the backpressure network that would disturb the equilibrium of the geoclald, 215 is part of the mechanism used to be placed on the Cylinders 210 and 210a are so arranged with respect to portions 215 that blades 214 and 214a are in continuous contact with the surface of chart cylinder 216. The method of use of this plug-in device is given below. Each chamber is independently pressurized. the current of which is independently regulated for each chamber. Every chamber! it has an independent connection to an alarm device and to cylinders 210 and? fOa. The pressure relief device 60 (Figures 3 and 4) allows the release of pressure only from the chamber 9 and the impact of the springs and other alarm communication, and in this case it takes place only with respect to the chamber 9. After moving the bolt, door chamber 9 and 10 remain under pressure from the main source, and the door is closed with latches18. Before the door 8 is to be opened, the pressure therein must come out in order to force the bolts 18 to reveal the slack of the walls, so when the door is opened, the chambers 9 and 10 will remain pressure-relieved. When the door is closed and locked again, the pressure from kom-cw- 6 and 7 of the wardrobe passes into compartments 9 and 10 of doors, causing a momentary load of pressure in compartments 6, 7 and figures 27, 27a, 209 and 209a, connected with By alarming and writing with a device, because of course there is a proper spring action, there is a fundamental difference between the opening and closing diagrams in such a way that the line marked by the blade 214 connected with the chamber 6 supplying the compressor 61 will be wobbly and quivering when the door is open, in this case it will be a line similar to it, outlined by a blade 214a connected to the chamber 7. And when the door is closed and bolted by a through bolt 12, both Knije will be slightly wobbly. 14 gives an example of the use of an audible alarm operated by a pressure system. The housing chamber has a door cage and a closing device as shown in Fig. 17. The side of the housing 217 has specific outlets connected to with chamber pressure. These devices, which permit the passage of the said outlets to escape from pressure, are placed at such an angle that it is impossible to insert any tool into the mechanism of the housing. Any damage or other interior of the casing is prevented by a strong screening mesh Mentioned outlets. The interior of the casing chamber 217 is provided with a transverse partition 220 which elastically binds to the spring 221 so that a clearance is created between contacts 222 and 223. Contacts 222 they are connected by a wire 224 which, along the way through wire 225, connects to clamp 226 of any suitable bell or motor 227. Wire 228 connects clamp 229 of a bell or motor with clamp 230 of battery 231. Contacts 223 connects Using wires 232 and 233 with terminal 231. When one or all of the contacts 222 come into line with one barrel and contacts 223, the current is closed and an alarm is triggered. This can occur if the plate 220 is loaded with some object that will increase its weight and cause it to vibrate on the spring 221. Conductor 235 connects the terminal 234 of the battery 231 to the contact 236, which is seated on the piston rod 237, which is under the influence of the spring. (immaculate) at the moment when the pressures of chamber 217 and the whole circuit are fused (Fig. 15). Contacts 238 and 239 are connected to the terminal 226 of the bell or motor by the aid of the -14-wire 24O. Contact 236 is centered between contacts 238 "and 239, and any increase or decrease in pressure causes contact 236 to be linked to contacts 238 and 239, whereupon the current is closed and an alarm is triggered. Fig. 21 gives a variation of the alarm devices. For cash registers or other objects with 2 or more chambers / Pistons 210 and 210a are provided at their trunks with alarm tubes 209 and 209a (Fig. 19), which can be used to trigger an electric signal in the following manner The piston 213 is provided with a fork contact 241a, the piston 213a with a contact bar 242. Contacts 241a and 241b are connected to terminal 243 connected by cable 244 to conductor 245 and terminal 246 of the fork contact 247. Contact pin 242 has a leak. 248, connected to the positive pole of the battery by the wire 249. The wire 245 connects to the negative pole of the battery. A buzzer can be connected to this circuit. The contact rod 242 has two contacts 242a and 242b, after coupled to clamp 248. Fork clamp 247 has similar contacts 247a and 247b; the clip is suitably secured and contact rod 242 so positioned that contact 242b ranges between 247a and 2476, and contact forks 241 are so positioned that contacts 241a and 242b are at equal distances from 242a. If contacts 242b come in contact with contacts 247a or 247b, the current is shut off, the same is true if 242a comes into contact with contacts 241a or 241b. The deliberation and sensitivity of setting the above contacts is achieved by preventing them from being possible. triggering a false alarm upon eventual temperature fluctuations. When the temporary bolts are removed, the openings of the door chambers remain under pressure, although the source of pressure has already been cut off. This pressure keeps the diaphragm bolts 18 closed. The construction of bolts 18 is made in such a way that their displacement ultimately depends on the vacuum condition generated in the entire contents of the chambers 9 and 10 of the doors, or b) that the above positions of the bolts are were caused by the production of vacuum only in a certain part of the contents of the door chambers. After releasing the pressure from the entire volume of chambers 9 and 10 according to point a), the pressure balance in the door valves and in the entire system will reappear when the door is closed without through bolt. Chambers with a smaller volume should be pressurized sooner than chambers with a larger volume. An alarm device connected to chambers with a smaller volume should respond to the pressure upstream of the device by such chambers with a larger volume. The simultaneous alarm is ensured by the action of the through-bolt 12 on both sides when rotating the common spindle 13. Operation of the alarm mechanism may be triggered at a predetermined point of rotation of the spindle and prior to the operation of any other alarm device of the same cash register; the two alarms may also be successive at a certain time interval. The desired time intervals can be fixed by the difference in the area of the opening under the action of the through-bolt or by changing the volume of the chambers, by introducing different for each bolt ttzone. The difference in the filling time of the chambers 9 and 10 doors can be fixed and determined on demand .Where pressure variations - 15 - only in some part of chambers 9 and 10 (point a and b), the abovementioned variations in the operation of the alarm mechanisms may be prevented by changing the caliber of perforated tubes 80 and 80a in each chamber and by connecting these tubes to a suitable valve located outside the door 8. The difference in size of the tubes in each chamber would equalize the volume of the chambers. With such an arrangement, an appropriate order of operation of the alarm mechanisms would be established and the time period between the alarms would be ¬ be determined by the appropriate amount of contained pressure escaping from each chamber through the external valve 99, All used and may To be used to secure a confined space, factors are covered by a reservation which also includes the description of giving an alarm signal on (In the event of the destruction of alarm signals that the cash register has been closed and opened, which would facilitate theft at a later time). 22 indicates the piston rod 213 actuated by the spring 212 of the alarm device (FIG. 19) attached in the chamber intended to be filled at the earliest by the through bolt 12 when the door 8 is closed. 250 and 251 are contact bands aa end of piston rod 213, 252 - table for contacts 253, 253a, 254, 254a, 255 and 256 - door attached to piston rod 213.257 - spindle with bar 258. 260 and 261 - spindle stops 257 for connecting and breaking contacts. The piston rod is actuated by a spring 2 / 2a of the alarm device (FIG. 19) attached to the chamber which requires a longer filling time through the through bolt 12 when the door is closed. 262 - contact strip at the end of the piston rod 213a, 263 - the base of the contacts 264 and 264a, attached to the stem 213a, 265 is a solenoid and 266 is a bell, 267 and 268 - a battery. The above device has a network and operation : wire 269 connects the positive pole of battery 267 to terminal 270 of contact 253. Wire 27 / connects the negative pole of battery 267 to the damp 272 of the bell 266. Wire 273 connects terminal 274 to the bell 275. Wire 276 connects contact 277 with terminal 288 contact here 253a. A lead 289 connects the positive pole of battery 268 to contact terminal 290 254 through breaker 260-261. Wire 291 connects terminal 292 of contact 254a to the negative terminal of battery 268 via breaker 260-261 and solenoid 265. Wires 293 and 294 are branches of the solenaid circuit and are connected to terminal 298 of contact 264, or each of wires 293 and 294 connects the solenoid circuit to the contacts. 293a and 294a so that this branch of the circuit is not affected by the breaker 260-261. 295 is the rod causing the rotation of the rod 275 to connect it to the contact 277 when the solenoid is inactive, 295 - the mole shaft to limit the vibration of the plate 275. Piston rod 213o. it is to be actuated (FIG. 22) by the pressure from chamber 9 which replenishes the pressure of the compressor 61, acting on the lifting of the ratchet tab. Since its movement is triggered by the contact strip only by the electrical connection between contacts 264 and 264a of the circuit in which solenoid 265 is connected, the alarm is not triggered in both directions. As the stem 213 retracts, the contact strip 251 joins the contacts 254 and 254a slightly earlier than the strip 250 joining the contacts 253 and 253a, and the link 254 and 254a is held by strip 251 until strip 250 passes through contact 253a. Although circuit breaker 260-261 is in the "closed" position during this time, bell 266 does not ring because solenoid 265 breaks the bell current circuit before it is closed and maintains this break until contact strip 250 will not open. 16 - Contact 253a. Once this has occurred, road 256 engages with rod 258 and actuates spindle 257 such that interrupter 260 - 261 becomes "broken". On the return drift of the stem 213, the contact strands 250 and 251 again come into contact with the contacts 253, 253a, 254 and 254a. The bell network is thus closed, but the solenoid circuit, closed at contacts 254 and 254a, is again interrupted by breaker 260-261, so that the solenoid cannot interrupt the bell current which now starts ring, Since the shaft 213a is coupled to a chamber of greater volume or mass than the chamber to which the piston 213 is attached, the shaft will emerge to its limit point more slowly than shaft 213, and swim this contact 263 of shank 213a may be relatively so arranged that any breaker 260-261 causes a current break, the circuit! solenoid 265 may be closed by a contact strip 262 connecting contacts 264 and 264a, so as to force solenoid 265 to interrupt the ring circuit 266, while contacts 253 and 253a of the ring circuit are connected by strip 250 on the return the piston path 213. This prevents the bell 266 from ringing during the return path of stems 213 and 213a. After shank 213 has returned and after strand 250 has passed contact 253, shank 255 advances spindle 257 by engaging shank 258, with interrupter 260-261 becoming "closed". When there are timing irregularities in shafts 213 and 213a , is announced by the bell 266 at the return path of the pistons. When water pressure is used for the closing and alarm system of the cash registers, pipes 21 and 19 which supply water pressure to chambers 6 and 7 are fitted with fusible necks so and in an explosive event, these plugs melt at a certain predetermined temperature, which causes the circulation of water through the chambers of the entire cabinet system and the door protecting the cash interior from the harmful effects of heat. there is a different pressure in the system, the wedge may be permanently connected by means of a tube 299 (FIGS. 1 and 2) to chambers 6 and 7 to activate the alarm device, and the pressure pad enters them when the stopper 300 melts, and the outlet of this water skimmed The water circuit in the system is arranged in the manner of so-called "sprinklers" or also in the manner of the communication of a hot wedge in a bathhouse. The discharge through the tube 301 should be greater. from the spout through the tube 299, so that the air in the chambers 6, 7, 9 and 10 exits sooner than the water flows through the tube 299, and so that pressure relief and alarm signals will necessarily be triggered when plugs 300 and 302 will be melted. The outside of all internal walls of the cash register may be provided with a curtain 303 (fig * 4) made of a suitable material. On this slurry there are bombs which explode in case of penetration of any tool into the chamber, Figures 23, 24 and 25 give an example of the application of the invention to protect a door. The door 305, rotatable on hinges 306, is provided with a rotating bar 307 and a bolt seat 308. This cross-member, when rotated, falls into the handle 310 and the segment (lower end) 311. The tube 312 receives pressure from the main source. This pressure may be regulated and applied to the door closing system. Tube 312 should face the wall of the building and face valve 313 in recess 314. Tube 316 connects valve 313 to valve 317, and valve spring 317 is applied to cylinder 318. Tube 319 -. 17 - connects to & Wór 313 with compressor 320. Tube 32Jf is a spline on compressor 320 and connects to valve 322 in cavity 314 which has door 323. Cylinder 318 includes piston 324 with spring 325, bolt 326 whose end moves in a guide ¬ niku 327 and the bolt socket 308. The bolt 326 is empty and under pressure over its entire length in the chamber 328 and is provided with a slot 329. Compressor 320 has a spindle 330 on which the disc is locked. 331 with a cable 332 attached to the valve 333. The outside of the spindle 330 has an arm 334 arranged so that it touches the end 335 and the claw 336. If the valve 313 is open, pressure is applied to the compressor 320 through the tube 319 up to the cylinder 3/8. through the tube 316; The spring-loaded valve 317 is opened. As pressure builds up in compressor 320 and 333, it is directed to the bottom of cylinder 320a, and valve 322 gradually equalizes the pressure of the plant with valve 333. Finally, the claw 335 falls into the section 339 of the bolt 326. To move the bolt 326, the valve 322 is opened and allows pressure to escape under the valve 333, which causes the valve 333 to lower and force the stick 334 to step on the tab. 336. When the pin 336 is thereby released from engaging with the bolt 326, valve 313 is closed (valve 322 remains open), cutting off all pressure from the compressor and cylinder; the tappet continues through the valves 333 and 322, reducing the pressure in cylinder 318, and then spring 325 forces piston 324 to retract along cylinder 318, thereby pushing piston rod 326 out of seat 308. in the closed position, slot 329 has a firm degree of opening to allow the latch 326 to be retracted before the tooth 333 is fully raised. 'Pressure forces the latch 326 to remain in the latched position, but when for some reason or by chance the pressure will drop, taking a different route than valve 322, and the claw 336 prevents the bolt 326 from moving away. The spring valve 317 is attached to its spring in a position, permitting pressure on cylinder 318, simultaneously closing the spline tube 338, and when it rotates, pressure hits the cylinder and unplugs cylinder 318 for tongue through the outlet. lot 338. Thereby the door 305 is opened to the outside of the building. Tube 339 applies pressure to the locking device and other doors, but if a building is to be secured with two or more doors, only one of them should be provided with a pressure lock and a compressor as described above, and others the door need only have cylinder 341, bolt 340, piston 342, spring 343, vacuum piston bolt 344, slot 345, and latch 346. As pressure builds up through tube 339 in cylinder 340, piston bolt engages and forces bar 307 to stop. Engage in buckle 310 and slot 311 and triimize it at this position as long as there is pressure in cylinder 340. When piston bolt 344 is fully extended, pawl 346 falls into crank 345 and closes bolt 344 at this position. In this case, bolt 344 acts as a locking bolt. When the main door of the building is thus secured, the bolt 346 is released by hand. Obviously, the two methods of closing the door 305 shown in FIG. 23 and described above cannot be applied to a single door. The tube 339, once assembled, is attached to the alarm device as already described. Fig. 26 shows an example of a pressure tube being used to secure a window in the rebate 347. The pressure tube is provided with the pressure tubes in any manner. The pressure enters the tube network through the end of the tube 348a and exits through the end of tube 348b to the alarm device. Raise 347 can be permanently attached to the wall or also suspended in hinges and be uncoal, and any of the above-mentioned means of securing can be applied to it. Figure 27 shows an explosion of a cord used as part of the attached string. the cable to be damaged by the inserted tool. The detonating cable has two parts 349 and 349a, held together with a soft material so that a low intensity is sufficient to tear both parts apart. Each of these parts is provided with links 350 and 350a for attachment to the common line lob of the chain. Part 349 has a flammable plug 352 to which alarm system wires 353 and 354 are connected. Inside part 349 is an explosive cartridge positioned in such a way to the plug 352 that the explosion occurs when parts 349 and 349a break, because then the electric current that ignites the plug 352 is closed. This allows the original to be forgotten. current of the alarm system, the emergence of a high voltage for this activity, eg by using a cord or chain 351, 351a, whereby the high voltage battery is turned off. When a cord or chain is broken, a spring-induced current shutdown occurs. Figures 28, 29 and 30 show the application of the principles of the invention to protect a bank from attack on a white day. The pipe 356 is kept under pressure from the correct pressure and is embedded in the interior wall of the building at a suitable height from the floor. It may enclose an entire building or just one room, but it is always terminated with a blank end 357. Tube 358 is intended to supply pressure to compressor 359 and may be positioned to supply other compartments or the like. . The tube 360 connects the tubes 358 and 356 and is provided with a valve 361 so that when it is open, the pressure penetrates tube 358 and compressor 359 In addition, there may be other connections for tube 360, but each must have a valve similar to 361. In Fig. 28, the number 362 denotes a box or drawer whose tab 363 can rest against the projection 364 when it is released from its closed position by the spring 366 by pulling on the trigger 367. This system is operated by the pressure from the compressor 359 by the gear 308. and 309,370 is a rod for extracting a box or drawer in a different way. 29 shows the same device except that portion 362 is held in balance by a spring used in place of the pulley and cable shown in FIG. 28, and a spring bolt 364 is used as a handle. PL PL

Claims (1)

1. The patent claims are in e. 1. The anti-burglary or fire alarm device and the devices for closing, securing and protecting coffers, vaults and the like, characterized by the territory, with the essential factor in this device being pressure to moveable parts of it executable in the system of activities securing the closing and opening of the doors of these rooms, 2. Security system according to. Claim 1, characterized in that that it consists of restrictive sandwiches, means for supplying the chambers with pressure, means for decontaminating or changing the temperature inside the chambers, means for closing the chambers and means for activating the closing devices using the pressure applied to the chambers, Changes which are closing and rinsing, and anti-rinsing agents, when the pressure is cut off or lowered below that necessary to enable unblocking, so that pressure changes are a factor of the indicative measures. 3. The security system according to claim 2, characterized by the fact that it has locking means in the form of tightly holding bolts and means for applying and isolating the pressure, the pressure-active bolts were applied through them and the ratchet release device. 4. The security system according to claim 2 and 3, characterized by a ratchet and a compressor for releasing the pawl. 5. The security system according to claim 2, 3 and 4, characterized by an electric alarm device and an explosive device operated by means of pressure devices. 6. The security system according to claim 2, 3f 4 and 5, characterized by the fact that it has a fusible plug placed under the pressure of water in the tube, which melts when the temperature is raised and allows the circulation of water in the chambers of the room at risk of fire. 7. A securing system according to claims 2-6, characterized in that the secured cash registers are surrounded by a smaller or larger number of chambers adapted to receive a liquid under pressure. 8. The security system according to claim 2-7, characterized by the fact that the pressure in it remains at! equilibrium is prevented by the resistance of the spring, while the imbalance causes the closing of the open circuit of the electric current and triggers alarm signals or other action. 9. The security system according to claim; 2-8, characterized by the fact that the pressure before entering the chambers of the system is regulated. 10. The security system according to claim 2-9, characterized by the fact that the constant flow of pressure in parts of the alarm device is responded to by a constant supply of the supply pressure. 11. Security system according to alternatives. 2-10, characterized by the fact that the drop in pressure causes it to leak, and the leakage causes a change in the resistance of the tube towards the reduction of the initial pressure and pressure at the end of the alarm system, and causes an equilibrium between the changed initial pressure and the resistance of the spring, balance makes an alarm. 12. Security system as per order. 2-12, characterized by the fact that the pressure drop at the end of the alarm system, the reduction of the pressure relief valve spring resistance and the use of a pressure regulator reduce the possibility of system imbalance due to allowable and normal temperature variations. 13. The security system according to claim 2 to 12, characterized by the fact that it is protected against an accident according to claims 2 to 12. 12, a thermo-static regulator is used in conjunction with a pressure-regulating device and an alarm device. 14. The security system according to claim 2-13, characterized by the fact that the use of non-return valves prevents backpressure and the flow of stress from the wrong source. 15. Security system According to claim 2-14, characterized by having alarm tubes or vacuum lines that are sensitive to any pressure changes. 16. The security system according to claim 2-15, characterized by the fact that it is kept in balance by the action of the siclenoid on the resistance of the spring. 17. The security system according to claim 2 to 16, characterized by the fact that its tubes and conduits are made of a variety of metals or compositions and of equal diameter. 18. Security system according to - 20 - reservation. 2-17, the stem is that the spindles of the door are empty and the inner ends of them are open. 19. The security system according to claim 2—18, characterized in that the first spindles, mentioned in item 18, are active by means of electric current or vacuum. 20. Security arrangement according to the provisions. 2-19, characterized by the fact that when the cash register door is closed and the main bolt closes it by turning the hand wheel outwards, closing the bolt reveals the valves in the cash register chambers, which flow through these valves under pressure, while the pressure flows into the chambers door until the pressure in the whole system will not be in equilibrium 21. Safety system according to the lock. 2 to 20, characterized by a number of small diaphragm bolts which serve as an auxiliary closing means. 22. The security system according to claim 2-21, characterized by the fact that the pressure tubes act as telephone lines for the (transmitting and receiving point. 23. Safety system according to claims 2-22, characterized by the fact that inside the chambers there are explosive bombs) after a perforation of the walls and a drop in pressure at the same time, which also causes an electric current alarm. 24. Safety system according to claims 2 to 23, characterized by the fact that in order to open the cash register, the tab of the tab is released from the swelling from the brake wheel, allowing the bolt to be moved away and cutting off at the same time the pressure supplying the cash register door, even though the pressure in the cash register door remains constant and the spring bolts are closed, 25. Safety system according to claims 2 to 24, characterized by the fact that the chambers are provided with a pressure regulator, a brake wheel and a ratchet device. 26. A safety system according to claims 2 and 25, characterized by a set of diaphragm bolts equipped with releasing springs, 27. The security system according to claim 26, characterized by a set of diaphragm bolts provided with a device for releasing them with a vacuum, 28. Safety system according to claims 2-27, characterized by having a set of reducing valves and artery devices. 29. The security system according to claim 2-28, characterized by a bolt and valve assembly for pressure supply, and a device and compressor for lifting bolts. 30. The security system according to claim 2-29, characterized by having a pressure gauge at the alarm device. 31. The security system according to claim 2-31, characterized by the fact that the factor causing the electric alarm is a fluid acting on its weight. 32. The security system according to claim 2-31, characterized by having a graphical device to visualize pressure changes. 33. The security system according to claim 2-32, characterized by the fact that its explosive device consists of chords of weakly welded, slightly tearing parts, which contain a cartridge that explodes when broken into two instruments by means of a plug. Morgan Cyprian Mc Mahon O * Br i en. Deputy: Dr. inz. M. Kryzan, patent attorney. To the patent description No. 6975. Ark. i. 6 £ a- // / J BK To Patent No. 6975. Ark. 2. ^^^ T ^^ yyy ^ y ^ NSS ^ STTCSl tSSESSSSSSSSSSSSS ^, ^ P fl {¦AU VWAlj glJiYiWpS ^ as lr ^ 36 D?! LlUll) l) ^ g ^ / j / ^^^; ^; // ^^ /// ^ / mezaJLy ^ 16 92 100 3a To patent specification No. 6975. Ark. 3. ^ VVVV \ VkV ^ VVV ^ CCCCu ^ lSSuIZXX2IX2XXS22 11 $ ° y Sr 50'44 33 45 To patent specification No. 6975. Sheet. 4. / 49dl 149 * Irc ^ TDo Patent No. 6975. Ark 5. www. Patent Specification NTr 6916. Ark. 6.a, m zw m 4- ui L U6 109 "Z! EL w tiW Ztó ur knows Z4-8 ¦a. Mn sW * Ym Ecu ^ isfe Z97 m? T / r, Tw zk fcU ^ y YZ9i • To Patent description No. 6975. Sheet 7. 346 540 546 34 $ '' '' * "X 539 * f6 AB ^^ 3? / $ 3/530 33ZD To patent specification No. 6975. Ark. 8. To the patent p. 6975. Ark. a. In f. in g. i rV7 / /// <¦ ^ f = ^ r ^ J ^ .Jtt Print by L. Boguslawski, Warsaw. PL PL