DE863879C - Power transmission device - Google Patents

Description

Power transmission device The invention relates to a power transmission device from a force generating means such as a temperature sensitive one Means on lein thrust element, for example a piston, and aims to be below Generating a high pressure a long way to achieve the thrust element, and especially for very small piston diameters.

For this purpose, the invention consists in that the preferably tubular housing of the device has a cavity-like closure part provided with a shoulder and an axially and openly adjoining guide part for a piston and in the closure part an at least part of the same in the transverse direction filling A flexible plug made of elastic material is arranged, which is movable with at least a part of its length under pressure in the guide rope and has such a resilience that it is laterally resiliently bent by the shoulder of the closure part during its movement towards the guide part, the pressure per unit area of the stopper against the shoulder during the movement of the stopper is greater than the pressure per unit area for moving the stopper and the piston is constantly held against the stopper and can be moved by it.

The subject matter of the invention is illustrated in the drawing, for example.

FIGS. 1 to 5 and 7 show different embodiments, FIG. 6 shows the embodiment of Figure 5 in a different position. The power transmission device has a preferably .rohr-shaped housing i, under which a, for example cup-like housing 2 is attached for receiving the force-generating agent, wvelches preferably made of a material with high thermal conductivity, such as brass, consists. The upper part of the device consists of a hollow. space-like housing, especially made of metal. The housing forms a closure part 9, an`, at the bottom. the. axially and openly lein guide ax q. for. a piston i o; connects and which is closed by a cap z 2 or the like. The case is below provided with a laterally circumferential flange 5, on which the lower cup-shaped Housing 2 is fastened by means of the beaded edge 3, 6.

The closure part 9 is designed as a cylinder 7 in its lower part, which has a larger diameter than the cavity 8 of the cylindrical guide part q, and merges into this with a conical part forming a shoulder.

For example, the inside diameter of the cylindrical guide part 7 about 6 mm and the inner diameter of the cylindrical part q. Be 5 mm, so that the - area ratio between parts 7 and 4 is greater than 112: i.

The piston io transmits the force through the piston rod io, which is guided through the cover 12. The piston io is under the action of a spring 13 which, for example, has a warning force of about. 1 q. kg / cm2 against the movement of the piston. The movement of the piston io towards the bore 7 is limited by its locking member, for example by a disk 14 of the piston rod ii. The locking member 14 is attached in such a way that the piston 1 6 cannot move into the conical part 9 of the brain.

In the closure part 7, 9 there is a flexible plug 16, which fills at least part of the same in the transverse direction and is made of elastic material, which is movable over at least part of its length in the guide part, for example made of vulcanized rubber, which guarantees permanent elasticity so that it may change its shape. can, but cannot flow under pressure. The plug 16 is preformed as a cylinder with a slightly larger diameter than the cylindrical part 7.

The housing 2 is filled by a temperature-sensitive means 15, which preferably: forms a tablet and can be composed of alkanes of high molecular weight or similar substances, which are intimately mixed with finely divided heat-conducting substance. An example of such alkanes is a hydrocarbon wax, preferably paraffin, which can be referred to as a mixture of solid hydrocarbons mainly of the methane group, which are derived from petroleum. For example, such a tablet can consist of 80 to 82 percent by weight of copper powder with a fineness of about 14o to 16o mesh and the 12th of alkanes or other> expandable binding material. The amount of powder used is like this; that, if the cup 2 were filled with the powder, it would overflow by at least an amount equal to that of the interior of the cylindrical part 7, and can be as much as 150% of the cup volume. The powder and the alkanes are produced in tablet form in a press that is capable of exerting a pressure of about 35okg / cm2 or even higher pressures. The result is that the expandable substance lies in extremely thin layers or coatings on the powder particles and fills the gaps, thereby increasing the speed of the tablet's response to temperature changes. The substance of the temperature-sensitive agent or the tablet 15 is therefore such that it does not flow freely under the conditions to which it is subjected in use and, since it is semi-solid or plastic, requires a certain pressure, which is 3, 5 kg / em2 and more in order to compress it again from the expanded state. Although the temperature-sensitive agent expands and contracts within the desired temperature range, the contraction when the temperature drops can lead to gaps that penetrate the agent inside, see above. that it does not return to its initial volume if it is not squeezed together when it is contracted. That is to say, the agent has an inherent resistance to volume reduction when the temperature drops.

The plug 16 is under a high degree of compression between the piston 10 and the tablet 15 due to the pressure of the spring 13, and the part 7, 9 i suitably contains a lubricant in order to promote the sliding movement of the plug 16. The length of the plug 16 is so dimensioned that it is not moved completely out of the bore 7 or through the shoulder g into the cylinder bore 8 when the material 15 is fully expanded.

The embodiment according to FIG. I works as follows: The lifting rod ii acts on any one. device to be actuated, for example a valve, a switch or a display device. When the temp: e; If the temperature of the agent to which the housing 2 is exposed reaches the desired working temperature, the tablet expands and thereby exerts a high pressure against the stopper 16. This pressure is sufficient to deform the plug or to compress it laterally so that it is upwardly through the tapered neck 9 to move the piston upwards against the force of the spring 13. to move. Since the plug 16 is not plastic, it is displaced by the pressure as a whole with sliding contact on the bore wall in such a way that its lower surface, which is in contact with the tablet 15, retains its flat surface shape, as shown by the line xx (Fig. i) is indicated. Since the heat transferring substance fills the space under the plug 1 6 more than, the substance is moved into the Bohrmig 7 as a result of its expansion, so that no accumulations or secretions of the substance 1 5 occur, which would otherwise be due to a change in the mutual position of the powder particles could happen, and there is also no stratification or agglomeration of the powder. The plug 16 has such a resilience that it is bent laterally resiliently by the shoulder 9 during its movement towards the guide part 8.

When the temperature drops, at which the tablet i 5 is cooled, contracts and finally hardens, the spring 13 moves the stopper downwards towards the housing 2. Since the plug 1 6 is elastic and is under deformation pressure due to its original cylindrical shape, the plug expands again, and fills the bore 7 while it is moved into it. The radially effected outwardly over the upper part i extending container 2, a hardening of the tablet 1 5 radially inwardly, so that the downward movement of the piston is io not prevented by an initial hardening of the tablet in the middle part of the container and below the. Stopper 1 6. Since the tablet 1 5 requires external pressure in order to return to its initial volume, the tablet cannot contract in such a way that a space is created between it and the stopper 1 6 , whereby the stopper comes into contact with the tablet 1 5 would lose if the piston io has reached its lower position on its downward movement. The plug 16 is therefore always under lateral pressure in the throat-shaped neck 9 between the piston 10 and the tablet 15, so that the possibility of leakage is excluded. Since the piston cannot enter the throat-shaped neck 9, the material of the stopper cannot heat around the edge of the lower end face of the piston and, on the next upward stroke of the piston, approximately into a free space between the piston io and the wall of the bore 8 are pushed or pulled. Since .the plug 16 undergoes no change in cross-section when passing through the pressure zone of the neck 9, its elastic material is prevented from sticking. The reduction in cross section when compressing the plug 1 6 in the neck 9 creates a; tight movable closure, the increase in the density of the stopper reducing the permeability of the rubber and largely eliminating osmosis. As a result of the elasticity of the plug 16, which counteracts its compression when moving through the tapered neck 9, there is an increase in the pressure per square centimeter in the circumference of the plug which is adjacent to the neck or is under pressure against it, which is the maximum represents the effective pressure per square centimeter as a result of the work involved in reducing the cross-section of the plug. This increased pressure is greater per square centimeter than the pressure per square centimeter exerted by the tablet on the stopper and therefore creates a pressure zone which prevents leakage at this point or beyond this point. As a result of the spring-back of the stopper 16, this increased pressure in the closure zone does not decrease so that it is equal to the pressure per square centimeter which is exerted by the tablet 15 during the rest periods. The pressure per unit area of the plug against the shoulder g is thus greater than the pressure per unit area for moving the plug when the plug is moved, and the piston io is constantly held against the plug and can be moved by it.

In the embodiment of FIG. 2, the closure part consists of your diverging part 2 i and an adjoining part after the guide part 8 converging part 2o. The part 2o thus forms at the transition of the locking bore 22 into the guide bore 8; an annular shoulder. The space under the flask i o is filled by the plug 23, the length of which is dimensioned so that it is not moved out of the part egg when the piston moves completely outward.

In the embodiment according to FIG. 3, the locking bore has mutually converging parts 30 and 3 i, so that the shoulder of the locking part is formed by a throat-like constriction. The locking hole is also here from one. Stöpaiel 32. Filled out of supple elastic material, and the stopper 132 has a length that it cannot move out of the part 3 i when the piston 8 moves completely outward.

In the embodiment according to Figure 4, the shoulder of the closure part formed by an inwardly projecting ring-like constriction 40. Below this Ein.chnürung the part 4 i is cylindrical. The closure part is through the stopper 42, which, as with the vorbes.chrieb@enen execution forms, 'also with complete outward movement of the piston not completely through the constriction 4o passes through.

In these embodiments, too, the locking plug is constantly under pressure from the side, so that even if a temperature-sensitive medium is used which contracts without external pressure on the original volume, the closure is still maintained by the piston return spring 13, which in the embodiment according to FIG . 2 so acts to zusammjendrückt the plug 1 6 in the zone 21, and compresses in the embodiments according to Figures 3 and 4 so that they chnürung the plug in the zone 3o or in one, 40.

In the embodiment according to FIGS. 5 and 6, the closure part 5o is expanded outwards from the guide bore 8 to the flange 5, so that: an annular shoulder is formed at the transition from the conically enlarged part 5o to the cylindrical guide part 8. Between the container edge 3 and the flange 5, a membrane 51, which is made of a rubber-like material such as neoprene, is attached and squeezed or pressed to a smaller thickness. The pressure on the circumference of the membrane 5 i is attached in such a way that the edge of the membrane is generally driven into an annular recess 5 and the edge is thereby tightened. The temperature-sensitive means 1 5 fills the container 2 and rests on the membrane 5 1. The closure bore 5o is filled between the membrane 5 1 and the piston io by a plug 52 made of the supple elastic material already described above, which can be preformed in the shape of a truncated cone, as shown in FIG. The plug 52 serves as an abutment for the membrane 5 i,., So that a relatively thin elastic membrane can be used. The thickness of the membrane can be about 0.00254 mm and is therefore significantly thinner than was previously possible. The membrane 5 i also serves a .dicht mating contact zwischam the plug 52 and the wall of the shutter hole maintain, so that no part of the membrane to the working pressure of the tablet 1 5 without support. The slightly over-dimensioned plug 52 is under lateral pressure and corresponding deformation and thereby prevents the contact of liquids with the membrane 5 i, which may leak through due to a play between piston 10 and bore 8 and exert a dissolving effect on the membrane or the inclination might have to penetrate the membrane by osmosis. The plug 152 and the entire surface of the membrane 5 i are constantly under considerable pressure, which increases their density and makes them less permeable, so that the possibility of an osmotic effect through the membrane is substantially reduced and completely avoided through the plug . If the materials of the membrane and of the temperature-insensitive agent are such that the membrane is usually permeable to the temperature-sensitive agent, a small amount of the latter may well pass through the membrane as a result of the pumping action when the device is operated. But this material which has passed through is prevented from escaping through the plug 152 and therefore comes to a standstill as a result of the equilibrium which is established on the opposite sides of the membrane. Furthermore, the high unit area pressures to which the membrane and stopper are continually exposed greatly reduce a dissolving effect resulting from their contact with solvents. When the desired operating temperature, about 6o ° is reached, .the tablet begins its effective 1 5 expansion or softening, the at; is complete approximately .7i °, moves the piston about io to about upwardly in the position of Fig. 6. The pressure exerted by the tablet is the same in all directions and presses the membrane 5.1 against the flange 5. Since the membrane 5i is pressed in on its edge ax between the container edge 3 and the flange 5, the part of the Membrane that rests directly on the tablet 1 5 , between the closure hole 5o and the edge 3, the substance that is expanded into the closure hole 50 and against the stopper 52 when the stopper is pushed upwards, and it the edge hatchet of the membrane attached between the edge 3 around the flange 5 is not subjected to any tension. The part of the membrane 5 i, which extends into the bore 5o and lays against its side wall, serves as an insulator or heat conduction resistance against the part of the tablet, len it encloses. The consequence of this is that, when the temperature drops, the tablet base within the cap formed by the membrane (FIG. 6) will cool less quickly than the tablet material in the bowl 2 and will have a temperature delay in relation to this, so. that the return of this tablet material and the piston io under the pressure of the spring 13 into the starting position of FIG. As for .the tablet 1 5 is an external force, such as that of the spring 13, required to be compressed when temperature decreases. be so. the tablet holds the membrane tightly against the stopper 52, and therefore there is no shrinkage of the tablet in the event of a further decrease in temperature when the piston reaches its lower limit of movement. As a result, no gaps can form between the membrane 51 and the plug 57, which could give rise to liquid being sucked inwardly around the plug. The height of the tablet overgrowth (Fig. 6) is reduced by a given movement of the piston or by reducing the piston area in relation to the opening of the cup 2, whereby the possibility that the tablet base hardens earlier than the rest of the tablet, is decreased.

The membrane can also be used in connection with the closure means or the plug of the embodiment @ s according to Fig. i to 4 are used, wherein then result in the same advantages.

In the embodiment according to FIG. 7, the bowl-like container 6o is crimped with the edge 61, 64 around the flange 63 of the cylindrical guide ax 62 for the piston 72. The flange 63 has a circumferential bevel, which forms a sealing channel with the edge 6 i. 64 -forms, in which a packing 65 made of rubber or the like. Is pressed. At the lower end of the guide bore 66 there is an annular rib 67, under which the closure bore 68 is located. The closure bore 68 is filled by a plug 69 made of flexible elastic material, while the chamber formed by the cup 6o and the flange 63 is filled with the temperature-sensitive material 70 , which in this embodiment surrounds the lower part of the plug 69 and the plug is under pressure against: the force of the spring 71 holds, which acts on the piston 72, which in turn is pressed onto the plug 69 by the spring 7 z. In this embodiment, when the fabric 70 is subjected to a temperature within the working range, it drives the plug 169 upward over the rib. 67 to move the piston 72 . The lateral deformation of the plug 69 as it passes through the area of lateral deformation pressure prevents any leakage around the plug. The plug, which is cylindrical in itself, is bulged in the shape of a barrel as a result of the external pressure, a wedge effect of the plug in the closure bore 68 and a second closure area being formed on the inner circumference of the flange 63 and at 73. This bulging of the stopper is a deformation caused by the hardening of the substance 7o at the bottom of the container 6o when the temperature affecting the substance 7o decreases, ie hardening in relation to the degree of hardening of the substance 7o on the sides of the stopper 69. The radial distance between the side wall of the container 6o and the plug 69 must be greater than the depth of the substance in the container 6o under the lower end of the plug at its highest level in order to ensure a suitable thermal gradient so that the hardening under the Stöpsel begins. This creates an effective resistance to the downward movement of the plug to ensure its bulging and the second. Form closure in the area 73. This embodiment has the particular advantage that the length of the device is reduced compared to the other embodiments.

Claims (3)

PATENT CLAIMS: i. Power transmission device, characterized in, that the preferably tubular housing (i) of the device has a hollow-space-like, provided with a shoulder closure part (9) and one .an these axially and open adjoining guide part (4) for a piston (io), and in the closure part a pliable plug filling at least a portion thereof in the transverse direction (16). Made of elastic material, which is arranged with at least one part of its Length is movable under pressure in the guide part and has such a suspension, that it moves through the shoulder of the closure part against the guide part is bent laterally resiliently, the pressure per unit area of the plug against the shoulder when the plug is moved is greater than the pressure per unit area to move the stopper and that the piston is constantly held against the stopper and is movable through this. 2. Power transmission device according to claim i, characterized marked that. to form the shoulder of the closure part on at least one Part of its length is conical with the taper towards the guide part is. 3. Power transmission device according to claim z, characterized in that the shoulder of the closure part is formed by a throat-like constriction which opens into the guide part (Fig.3). 4 .. Power transmission device according to claim i, characterized in that the closure part has a diverging part that adjoins it and converges towards the guide part (Fig. Z). 5. Power transmission device according to claim i, characterized in that the shoulder of the closure part is formed by an inwardly projecting ring-like constriction (Fig. Q.). 6. Power transmission device according to claim i, characterized in that the plug consists of a vulcanized, constantly elastic material and is squeezed in its full cross-sectional part through the shoulder or narrowing of the closure part under a distorting pressure. 7. Power transmission device according to claim i, characterized in that the closure part is provided at the lower end with an outwardly protruding flange and is closed by a membrane which is pressed with its edge against the flange, such that the part located within the pressed-on edge the membrane has a greater thickness than its edge, whereby the lower surface of the stopper forms a permanent contact surface for the part of the membrane that is not pressed on (Figs. 5 and 6). B. Temperature-responsive power transmission device according to claim 1 or 7, characterized in that a temperature-sensitive means (15) acts on the plug or the membrane and fills a chamber provided under the closure part. 9. Power transmission device according to claim 8, characterized in that the temperature-sensitive agent changes its hardness when the temperature changes and becomes harder when the temperature decreases. ok Power transmission device according to claim 8, characterized in that the membrane located between the temperature-sensitive means and the plug envelops part of the same when the temperature-sensitive means expands and rests against the wall of the closure part, so that the enveloped part is insulated against a decrease in temperature , the piston reducing the volume of the agent as the temperature decreases (4bb. 6). i i. Power transmission device according to claim 8, characterized in that the guide part adjoins the chamber with a constriction which contains a plastic temperature-sensitive agent, that the plug protrudes into this chamber and that ! the temperature-insensitive agent in the The part of the plug protruding into the chamber holds (Fig: 7). 12. Power transmission device after claim ii, characterized in that the radial thickness of the uniformed part of the stopper plastic material is greater than the height of the same under the plug, so that at a temperature decrease in temperature a hardening of the substance first below, however, the stopper begins (Fig. 7).