RU66482U1 - BASIS OF PNEUMATIC SUPPORT - Google Patents

Description

This technical solution relates mainly to lighting installations. It is intended mainly for its use in lighting engineering and can also be used in inflatable pneumatic construction supports.

Known bases [1-3] of pneumatic supports used in lighting and construction supports, each base comprising a bottom, means for attaching to the bottom of the air blower in the support, means for attaching the shell to the base, each base being made in the form of a box including a lower supporting part for supporting the base on the ground and the upper part, which performs the function of the bottom of the base, and in the bottom of the base there is a hole for supplying air to the shell of the support.

At the base [3], the bottom is made separately from the lower part of the base and is located above the base box and connected to this part by known means, and at the base [2] the bottom is located under the top sheet of the base box.

Known pneumatic bearings, the base of each of which is made of a flexible inflatable shell, in which at least one hole is made for pumping air into the shell [4-8].

In known lighting installations [1, 2, 9], in each of which the base of the support includes a bottom adjacent to the shell of the support, the bottom of the support is mounted on a stand and rigidly connected to the latter, while the mounting problem in [1 and 2] has not been solved , in particular, there are no means for connecting the supercharger electric motor to the bottom.

In lighting installations [9, 10], electric motors with air blowers (impellers) are located on the bottoms of the support bases, and in [10], an air compressor electric motor and a control unit are located and fixed on the bottom of the support base, by which the operation of the electric motor and the lamp of the installation are controlled.

Of the known closest to the technical solution presented in this description is the base of the pneumatic support, containing a bottom with an opening for the passage of compressed air through it, means for attaching to the bottom of the air blower in the support and means for attaching the shell to the base [10].

In this technical solution, the means for attaching the shell to the base includes a plurality of connecting elements, by means of which the shell is connected to the bottom of the base, the bottom being made in the form of a flat flange or plate mounted on a base stand in which the plant controls are placed. Essentially, the base of the installation support is made of two nodes rigidly interconnected, one of which is a bottom with an electric motor and a control unit attached to it, and the other node is a stand with control elements attached to it, while the said nodes are interconnected by means of many connecting elements.

This technical solution has a relatively complex design, which complicates the production technology of the bases of pneumatic bearings and leads to significant manufacturing costs.

Solved technical problem is to simplify the design of the base.

The stated technical problem is solved in that at the base of the pneumatic support, containing a bottom with an opening for compressed air to pass through it, means for attaching to the bottom of the air blower in the support, means for attaching the shell to the base, - a wall is connected or made integral with it around the bottom, forming with the bottom of the chamber under the supercharger and

support control unit, means for fixing the shell are made on the wall, and holes for support controls are made in the wall.

In the chamber, there is a means for securing the blower, which is made in the form of a bell connected to the bottom or made at the same time as a bell under the blower, while the bell is located in the chamber above the bottom opening or above the plurality of openings in the bottom.

The wall, bottom and bell of the base are one solid molded structure made of plastic.

The wall and the bell are made in the form of cylindrical individual elements rigidly connected to the bottom by detachable joints.

The means for attaching the shell to the wall is made in the form of a fixing belt closed around it for interacting with the shell and the clamp, or in the form of an annular groove on the outer surface of the base for interacting with the shell when the clamp is pressed against the wall of the base.

In the socket, a support is made for the supercharger, and the holes forming the air grill in the bottom are located under the support.

Figure 1 shows the base, front view; figure 2 is a view of figure 1; figure 3 is a view of B in figure 1; figure 4 is a view In figure 1; figure 5 is a spatial image of the base, top view; figure 6 is a spatial image of the base, bottom view; figure 7 - components of the pneumatic bearings installed in the base; on Fig - shows a base made of individual elements welded or interconnected by known means of connection (second execution of the base); figure 9 - the first execution of the connection of the engine with the bottom by means of a bell; figure 10 - the second execution of the connection of the engine with the bottom by means of a motor flange; figure 11 - the first embodiment of the means of fixing the shell on the wall of the support, made in the form of an annular belt; in Fig.12 - the second

the execution of the means of fixing the shell on the wall of the support, made in the form of an annular groove.

The base 1 (Fig. 1) of the pneumatic support comprises a bottom 2, as well as a means of fastening to the bottom 2 of the air blower described below, made in the form of a bell 3. The base comprises a girdle 4 located on its outer surface. The girdle is a means of attaching the shell described below to the base.

The base has a wall 5 made around the bottom 2 and associated with it, forming a volume chamber 6 (Fig. 5) with the bottom under the supercharger and under the support control unit described below. The belt 4 in one design is made integral with the wall 5 (Fig.1-7). In another embodiment (Fig. 8), the belt 4 is made separately from the wall 5. In the latter case, the belt 4 is rigidly fixed to the wall 5. In both versions, the belt 4 protrudes from the wall 5 to the outside.

The bell 3 (Fig. 3, 7, 8) for attaching the supercharger is located in the chamber 6, formed by the wall 5 and the bottom 2. The bell has a cavity 7 under the air blower (Fig. 5). The supercharger is an electric motor with an air impeller connected to the rotor of the electric motor. At the bottom there is one hole 8 (Fig. 8) or a plurality of holes 8 (Figs. 3, 4) communicating the bell 3 with the atmosphere. The hole 8 can also be made in the wall 5 of the base and communicated with an air duct (not shown) with the cavity of the socket 3, while the said duct is located between the wall 5 and the wall of the socket 3.

In one design (FIGS. 1-7), wall 5, bottom 2, and bell 4 are one solid cast construction made, for example, of plastic.

In another embodiment (Fig. 8), the bottom 2 of the wall 5 and the socket 3 are made in the form of separate elements, the wall 5 and the socket 3 are rigidly connected to the bottom 2, and the girdle 4 is rigidly connected to the wall 5 by detachable connections (not shown). In this embodiment, the wall and the bell are made in the form of volumetric shells, each of which has a cylindrical or oval, or polygonal cross-sectional shape.

In the socket made support 9 (Fig.3, 5) under the supercharger. The support 9 is a shelf made on the inner surface of the socket 3. Many holes 8 in the bottom 2 (Figs. 3, 4) form an air grill located under the support 9. On the lower side 10 of the bottom 2 there is a socket 11 for the air filter described below. The air supercharger is mounted on the elastic ring 12.

An embodiment of the base of the pneumatic support without a bell 3 is provided. In this case, means 2 (not shown) are provided in the bottom 2 for fastening to the bottom 2 of the electric motor 13, and means (not shown) are provided for protecting the control unit 14 from exposure to air and airborne dust. In this embodiment, the support base is selected, for example, a flange motor and mounted on the bottom 2 by means of a flange rigidly connected to the stator of the motor, a flange (not shown). In this case, the electric motor is selected with an air cooling casing having air channels for passage of cooling air flow through them.

7 shows a wiring diagram: base 1, elastic ring 12, blower motor 13, air support control unit 14, base cover 15, filter 16 and removable buttons 17 of the support control unit.

In the wall 5, holes 18 are made for removable buttons 17 of the control unit. A hole 19 is made in the cover 15 for the fixing element 20 for fixing the electric motor 13 on the cover 15. The inflatable flexible shell 21 of the pneumatic support in its working position is conventionally shown by dotted lines (FIGS. 5, 8). The flexible sheath 21 is also shown in solid lines at its attachment points. The latch 22 of the shell is made, for example, in the form of a clamp. Openings 23 are made in the cover 15 for air to pass through them from the air blower into the casing 21. The air blower is a propeller or an air impeller 24 connected to the rotor of the electric motor 13.

Figure 10 shows the flange 25 of the motor 13, which is connected to its air cooling jacket 26, made in the form of a casing. An air cavity 27 is formed between the jacket 26 and the motor housing, communicating with the atmosphere through a central opening 28 of the motor flange 25.

Position 29 in Fig.12 shows the annular groove 29 made in the wall 5 of the base of the support.

The assembly of the components of the pneumatic support in the composition of the molded base made of plastic is as follows. Install the elastic ring 12 (Fig. 7) on the support 9 in the socket 3 of the base, then install the motor 13 on the elastic ring 12 and fix the motor in its working position in the socket 3. Install the control unit 14 in the chamber 6 and fix it in the working position. Insert buttons 17 into the holes 18 and connect them to the control unit. Close the base 1 with the cover 15 and fix it in the working position so that the element 20 ensures that the electric motor 13 is fixed in the hole of the cover 15 in the working position. Then, the sheath 21 is mounted on the belt 4 and fixed with a latch 22 on the base wall 5, while the latch presses the sheath against the wall 5 and abuts against the lower surface of the belt 4. Install the air filter 16 in the socket 11 and fix it in the working position.

The assembly of the components of the air support from the prefabricated individual elements of the base (Fig) is as follows. Wall 5 and a socket 3 are connected to the bottom 2 and the girdle 4 is connected to the wall 5 as shown in Fig. 8. Then, in the sequence described above, these components of the pneumatic support are connected to the base 1.

The electric motor is turned on and the air impeller 24 is rotated, which rotates and draws air from the atmosphere through a filter 16, a bell 3, and pumps air through the outlet openings 23 in the lid 15 into the cavity of the shell 21. The latter is inflated, becomes stiff and supports placed at the top of the light source or as

antenna supports, either as a temporary support for a power line or as another, load bearing, inflatable support.

An option is provided for supplying compressed air from an autonomous air source, for example, remote from a pneumatic support, compressor, or air pump (not shown). In this case, an air hose (not shown) connected to the autonomous air source is inserted into the hole 8 (Fig. 8), and compressed air is pumped into the shell 21 through the bell 3. In this case, the use of the bell 3 prevents contact of the control unit 14 with air having microscopic dust particles passing through the filter, which reduces the dusting of the control unit 14 and positively affects its operation and the operation of the support. At the same time, the electric motor installed in the bell 3 is intensively cooled by the air passing through the bell, which eliminates overheating of the electric motor and also positively affects the operation of the support.

In the case of execution of the base of the pneumatic support without a bell 3 (Fig. 10), an air blower or an electric motor 13 with an air impeller is attached to the bottom 2 by means of a motor flange 25, a means for protecting the control unit 14 from exposure to air and air dust is installed in the chamber 6, and closed the cover 15 and the cover fixes the upper part of the electric motor from it and axial radial movements during the operation of the support.

During operation of the pneumatic support, air from the impeller 24 passes through the air channels 28 of the motor casing, between the air jacket of the electric motor and its stator, cools the latter and exits through the openings 23 in the cover 15 into the cavity of the shell 21.

1. US 6322230 B1, 11/27/2001. 2. WO 02/063207 A1, 08/15/2002. 3. FR 2736706, 01.17.1997. 4. SU 887879, 12/07/1981. 5. SU 684656, 09.15.1979. 6. SU 169576, 06/11/1965. 7. SU 392579, 11.23.1973. 8. SU 446603, 05/04/1975. 9. RU 2286510 C2, 10.27.2006. 10. RU 2192581 C2, 11/10/2001 (prototype).

Claims (6)

1. The base of the pneumatic support, comprising a bottom with an opening for compressed air to pass through it, means for attaching to the bottom of the air blower in the support, means for attaching the shell to the base, characterized in that a wall is formed around or connected to the bottom, forming one with the bottom a chamber for the supercharger and a support control unit, a means for fixing the shell is made on the wall, and holes for the installation controls are made in the wall. 2. The base according to claim 1, characterized in that in the chamber there is a means for securing the supercharger, which is made in the form of a socket connected to the bottom or made at the same time as a socket under the supercharger, while the socket is located in the chamber above the bottom opening or above a plurality of holes in the bottom . 3. The base according to claim 1, characterized in that the wall, bottom and socket of the base are one volume cast construction made of plastic. 4. The base according to claim 1, characterized in that the wall and the bell are made in the form of cylindrical separate elements rigidly connected to the bottom by detachable joints. 5. The base according to claim 1, characterized in that the means of attaching the shell to the wall is made in the form of a locking belt protruding to the side of the wall closed around it for interaction with the shell and clamp or in the form of an annular groove on the outer surface of the base for interaction with the shell when her tightening the clamp to the wall of the base. 6. The base according to claim 1, characterized in that in the socket there is a support for the supercharger, and the holes forming the air grill in the bottom are located under the support.