RU201328U1 - FLUID SUPPLY DEVICE - Google Patents

Abstract

The device relates to hydraulic transport using gas pressure. A device is claimed, comprising a housing with an inlet for a working gas and an outlet for a fluid working medium, a chamber made of an elastic material in the form of a cup, with the open side facing the outlet and connected to the housing at approximately half the height of the internal cavity of the housing, placed inside the housing element installed in the outlet pipe. On the side of the bottom of the chamber, a through hole is made of an elastic material in the housing, in which an additional sealing element is installed, which isolates the inner cavity of the device from the environment and is connected to the bottom of the chamber by means of a mechanical connection. The device provides remote control of the fact of operation. For this purpose, the device is equipped with a gas pressure sensor, and the outlet of the through hole made in the housing from the side of the chamber bottom is pneumatically connected to the pressure sensor through an additional branch pipe. The technical result consists in increasing the performance and reliability of the device by providing remote monitoring, which allows registering the actual fact of triggering, which should be understood as the moment of complete completion of the process of transporting the required amount of working fluid to the consumer. 1 ill.

Description

A device for supplying a working fluid (TPC) refers to hydraulic transport using gas pressure and can be used to supply lubricant to the rubbing parts of mechanisms.

When studying reference and patent funds, analogues of the proposed device were identified, including:

- a device for feeding TRS using gas pressure, given in the patent for a useful model RU No. 130370, MGZh F16N 7/30, publication 20.07.2013, B.I. No. 20. The device contains a source of working gas and a container with an outlet pipe. Inside the container there are: a chamber made of elastic material filled with TPC, a collector installed with the possibility of outputting TPC, and a sealing element installed in the outlet branch pipe of the container. In addition, the device contains a gas release mechanism that ensures the safety of the chamber made of elastic material after the device is triggered, and a system for activating the components. In this case, the source of the working gas is connected by a pipeline with the gas supply channels to the outer surface of the chamber, as well as with a gas bleeding mechanism, which contains a drain valve and an actuation delay unit.

Transportation of TRS to the place of their consumption using this analogue of the proposed device is achieved by compressing the pressure of the working gas into the elastic chamber.

The disadvantages of this tax include the technical complexity and unsatisfactory overall and mass characteristics of the gas bleed mechanism used in its composition, which requires an external energy source to operate;

- a device for supplying TRS using gas pressure, given in patent RU No. 2223441, MPK9 F16N 7/30, 11/10, publication 10.02.2004, B.I. No. 4. The device contains a housing with an inlet for the working gas and an outlet for TRS. The housing contains: a chamber made of elastic material filled with TPC, a cavity for the working gas, isolated from the chamber, and a collector installed inside the chamber with the possibility of removing TPC from it. In this case, a sealing membrane is installed in the outlet pipe. The housing is connected to the working gas source by a pipeline in which a gas bleeding mechanism is installed in the form of a throttling element with a low throughput.

Transportation of TRS to the place of their consumption using this analogue of the proposed device is also achieved by compressing the pressure of the working gas into the elastic chamber.

It should be noted that the gas bleed mechanism in the form of a throttling element with a low throughput is compact and does not require an external power source to operate. However, regardless of the place of its installation in the device, it also has a significant drawback, which is that, due to the low throughput of its throttling element, it is very sensitive to the purity of the working gas and, in practice, is not operational when using a generator-type gas source. As a result, this can lead to a failure of the operation of this analogue of the device, as a result of which the reliability of its operation decreases;

- a device for feeding TRS, given in patent RU No. 2466327, IPC F16N 7/30, F16N 11/10, publication 10.11.2012, B.I. No. 31. The device contains a housing with an inlet for the working gas and an outlet for TRS. Inside the body there is a chamber made of elastic material, having the shape of a cup in longitudinal section, with its open side facing the outlet pipe. The chamber is connected to the body and installed with the possibility of supplying the working gas to its outer surface. Outside the chamber, in front of the outlet, a collector is installed with the possibility of outputting TPC through it. The junction of the chamber with the body is located from the collector at a distance commensurate with the height of the chamber. A sealing element is installed in the outlet pipe. At the same time, this device has an embodiment, in which an additional pipe can be made in the housing on the side of the inlet pipe, connected to the channels for supplying the working gas to the outer surface of the chamber. In this additional branch pipe, a mechanism for venting the working gas can be installed in the form of a throttling element with a low throughput.

As mentioned above, the gas venting mechanism in the form of a throttling element has a significant drawback regardless of its installation location in the device. In addition, when this analogue of the device is triggered, starting from the moment it enters the internal cavity, and further throughout the entire process of performing useful work to squeeze the TRS out of the housing, at the same time, the working gas flows out of the internal cavities of the device through the throttling element into the environment. Due to this, the effective pressure of the working gas decreases, which leads to an additional significant decrease in the operability of the device.

It should be noted that when this analogue of the proposed device is triggered, the TRS is squeezed out not during the compression of the chamber, as in the previous analogs, but by turning the cylindrical part of its wall up to the stop in the surface of the inner cavity of the body and the bottom into the collector.

In addition, it should be noted that all of the above analogs have a common disadvantage, which is that, if used on small-sized objects, their design practically excludes the possibility of remote control of the device triggering process or, at least, its last stage, that is, the moment of complete completion of the process transportation to the consumer of the required amount of TRS. To date, an acceptable method of such control under the specified conditions of use of the device is unknown.

It is also known a device for feeding TRS, given in patent RU No. 2674818, IPC F16N 7/30, F16N 11/10, publication 13.12.2018, B.I. No. 35. The device contains a housing with an inlet for the working gas and an outlet for TRS. Inside the body there are: a chamber made of an elastic material in the form of a cup, with the open side facing the outlet pipe and connected to the body at approximately half the height of the inner cavity of the body, a TPC outlet collector and a sealing element installed in the outlet pipe. On the side of the bottom of the chamber, a through hole is made of an elastic material in the housing, in which an additional sealing element is installed, which isolates the internal cavity of the device from the environment. In this case, the additional sealing element is installed with the possibility of pneumatic connection when the device of its internal cavity is triggered with the environment due to the mechanical connection of the additional sealing element with the bottom of the chamber.

It should be noted that when this device is triggered, the TPC is squeezed out in the same way as in the previous analogue, that is, by turning the cylindrical part of the chamber wall made of elastic material in the surface of the inner cavity of the body and the bottom into the collector until it stops.

This device eliminates most of the shortcomings that were noted in the analogs listed earlier. This is largely achieved due to the fact that in this device the gas bleeding mechanism is made using an additional sealing element installed with the possibility of pneumatic connection when the device of its internal cavity is triggered with the environment due to the mechanical connection of the additional sealing element with the bottom of the chamber made of elastic material. In this case, the exhaust working gas is vented through a channel with a large throughput, which is operable with gas sources, both balloon and generator types. For the period of time required for the complete operation of the device, its internal cavities are isolated from the environment, and therefore the working gas is used with a higher efficiency to perform useful work on squeezing the TRS out of the case and transporting it to the consumer. When this device is triggered, the moment of bleeding the exhaust working gas into the environment is synchronized with the moment of triggering, which excludes the possibility of premature leakage of the working gas and contributes to the possibility of eliminating the causes leading to a possible failure of its operation. Thus, without using an external source of energy for activation in this device, the internal cavities are pneumatically connected to the environment at a strictly set point in time - after the end of the process of squeezing the TRS out of the chamber and housing, that is, after the device is triggered.

However, the design of this device, like that of the above analogs, in the case of use on small-sized objects, practically excludes the possibility of remote control of the process of its operation.

This device was chosen as a prototype as the closest in technical essence and the achieved result.

The objective of this utility model is to provide the possibility of remote control of the device actuation with registration of the actual actuation fact and maintaining the reliability of operation.

When using the proposed utility model, the following technical result is achieved - the performance and reliability of the device are increased by providing the possibility of remote monitoring, which allows registering the actual fact of device operation, which should be understood as the moment when the process of transporting the required amount of TRS to the consumer is complete.

The solution to the problem and the achievement of the technical result is ensured by the fact that in the device for supplying TRS using gas pressure, containing a housing with an inlet for the working gas and an outlet for TRS, placed inside the housing: a chamber made of elastic material in the form of a glass, with the open side facing to the outlet pipe and connected to the body approximately at half the height of the inner cavity of the body, and a sealing element installed in the outlet pipe, from the bottom of the chamber made of elastic material in the body there is a through hole in which an additional sealing element is installed that isolates the inner cavity of the device from the surrounding medium, and connected to the bottom of the chamber by means of a mechanical connection, according to the utility model, the device is equipped with a gas pressure sensor, and the outlet of the through hole made in the body from the bottom of the chamber is pneumatically connected to the pressure sensor through an additional pipe.

Thus, the proposed device contains the following distinctive features:

- the device is equipped with a gas pressure sensor;

- at the outlet of the through hole in the housing from the side of the bottom of the chamber, an additional branch pipe is made;

- the outlet of the through hole made in the housing from the side of the bottom of the chamber is pneumatically connected to the pressure sensor through an additional branch pipe.

The supply of the device with a gas pressure sensor makes it possible to remotely monitor the actual actuation of the device by using a pressure sensor as a measuring transducer of gas pressure into an electrical signal for its further registration.

The implementation of an additional branch pipe at the outlet of the through hole in the housing from the side of the bottom of the chamber makes it possible to supply the pressure of the exhaust working gas to the measuring transducer (gas pressure sensor).

The pneumatic connection of the outlet of the through hole made in the housing on the side of the bottom of the chamber through an additional branch pipe with a pressure sensor makes it possible to remotely monitor the actual fact of operation, thereby increasing the performance and reliability of the device.

It should be added that a high degree of sealing is not required for the pipeline of the remote control system of this device, and it will not have a negative impact on the reliability of the device, since this pipeline uses the exhaust working gas. As a consequence, the technical requirements for the pressure sensor that can be used in this device can also be greatly simplified.

The listed distinctive features of the proposed device in the aggregate provide the possibility of solving the problem of the utility model formulated above and achieving the specified technical result.

An example of the device is illustrated by illustration.

The illustration shows an embodiment of the proposed device, in the housing 1 of which are made: an inlet 2 for a pipeline from a working gas source (not shown in the illustration) and an outlet 3 for a transport pipeline for TRS going to the consumer (not shown in the illustration). Inside the housing 1 there is a thin-walled chamber 4 with a blank bottom, which is made of elastic material and in the longitudinal section has the shape of a glass, with its open side facing the outlet pipe 3. A collector is installed in front of the outlet pipe 3 to remove the TRS 5 from the inner cavity of the housing 1. Chamber 4 with the help of an insulating element in the form of a T-shaped collar, located approximately half the height of the inner cavity, it is connected to the housing 1 with the possibility of supplying the working gas to its outer surface due to the nozzle 2 and channels 6. In the outlet nozzle 3, a sealing element 7 is installed in the form of a cap with a destructible element (not indicated in the illustration).

On the side of the bottom of the chamber 4, a through hole 8 is made in the housing 1, in which a sealing element 9 is installed. Due to the mechanical connection of the sealing element 9 with the bottom of the chamber 4, a pneumatic connection is provided when the device of its internal cavity is actuated with the environment.

In this exemplary embodiment of the device, the sealing element 9 is made in the form of a movable plug, and on the outer part of the bottom of the chamber 4 there is a local thickening 10 with a projection 11. The projection 11 on the chamber 4 is connected by means of a flexible rod 12 with a similar projection 13 at the end of the sealing element 9. Length flexible rod 12 is installed commensurate with the height of the inner cavity of the housing 1.

On the housing 1, at the outlet of the opening 8, in which an additional sealing element 9 is installed, a branch pipe 14 is made for pneumatic connection with elements of a remote control system for the fact of device actuation, which contains a pipeline and a gas pressure sensor (not shown in the illustration).

It should be noted that due to this, the claimed device achieves the possibility of using, as a working signal for a remote control system, a freely recorded process of the change in time of the pressure of the exhaust working gas flowing out of the device. The outflow of the working gas from the device body occurs at an initial pressure of at least 50 kgf / cm ² and a final pressure equal to the ambient pressure, at a strictly set point in time - after the end of the process of squeezing the TRS out of the chamber and the body, that is, after the device is triggered. In this case, the gas pressure sensor (not shown in the illustration) can record the actual actuation of the device, which corresponds to the moment when the process of transporting the required amount of TRS to the consumer is complete.

The present utility model is not limited to the given example.

The device shown in the illustration works as follows.

When an operation command is given, the source of the working gas is switched on (not shown in the illustration). The working gas through the pipeline (not shown in the illustration) through the nozzle 2 enters the housing 1, while through the channels 6 it reaches the walls of the chamber 4.

Under the action of the pressure of the working gas, the walls of the chamber 4 move away from the inner surface of the housing 1, and then the chamber 4 is turned inside out (the final and intermediate positions of the chamber wall are not shown in the illustration) until the cylindrical wall of the chamber stops at the surface of the inner cavity of the housing 1, and the bottom of the chamber is in collector. At the initial stage of everting out the chamber 4, the increasing pressure of the TPC 5 acts on the sealing element (cap) 7. After reaching a predetermined pressure level at the cap, a destructible element breaks through (not indicated in the illustration). As a result of the subsequent action on the walls of the pressure chamber of the working gas TRS 5 through the outlet pipe 3 is squeezed out of the inner cavity of the housing 1 and through the transport pipeline (not shown in the illustration) enters the place of its consumption (not shown in the illustration). At the final stage of turning the chamber 4 (due to the connection by means of a flexible rod 12 of the projection 11 on the outer part of its bottom with a similar projection 13 on the sealing element 9), the flexible rod 12 is first straightened and stretched, and then the sealing element 9 is removed from the hole 8 towards the inner cavities with the possibility of outflow from the housing 1 of the working exhaust gas.

It should be noted that the end of the final stage of eversion of the chamber 4 corresponds to the moment of delivery to the consumer of the required amount of TRS.

In this case, the exhaust working gas through the opened hole 8 begins to flow into the remote control system of the fact of the device actuation, pneumatically connected to the branch pipe 14 (the elements of the remote control system containing the pipeline and the gas pressure sensor are not shown in the illustration). After the remote control system is triggered, the exhaust working gas is released into the environment (not shown in the illustration), and the process of transporting TRS to the consumer is automatically terminated.

After that, the walls of the chamber 4 do not experience excessive pressure and can be intact for a long time.

For repeated actuation of the claimed device, the chamber 4 is again filled with a predetermined amount of TRS 5, and the cap 7 with a destructible element is replaced with a new one. For the manufacture of chamber 4, a rubber compound is used. The body, the collector and the cap 7 are made of aluminum alloys, the flexible rod 12 is made of polyamide (nylon) threads or steel rope.

If the device is executed according to the proposed utility model, the following technical result is achieved - the operational performance and reliability of the device are increased by providing the possibility of remote monitoring, which allows registering the actual fact of device operation, which should be understood as the moment when the process of transporting the required amount of TRS to the consumer is complete.

Claims (1)

A device for supplying a working fluid using gas pressure, comprising a housing with an inlet for a working gas and an outlet for a working fluid, a chamber made of an elastic material in the form of a cup, with the open side facing the outlet and connected to the housing by approximately half the height of the internal cavity of the housing, and a sealing element installed in the outlet pipe, from the bottom of the chamber made of elastic material in the housing there is a through hole in which an additional sealing element is installed, isolating the internal cavity of the device from the environment and connected to the bottom of the chamber by means of a mechanical connection , characterized in that the device is equipped with a gas pressure sensor, and the outlet of the through hole made in the housing from the bottom of the chamber is pneumatically connected to the pressure sensor through an additional pipe.

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