NL8200536A - Air driven ejector to feed glass wool etc. into cavity wall - has compressed air entry orifices in converging portion of transport passage - Google Patents

Abstract

The ejector (1) is intended for introducing insulating material such as glass wool or rock wool into the cavity of a cavity wall. The material is drawn from a supply line (at 2) into a central passage (7,7',7") by vacuum created by compressed air (e.g. at 6) fed into a conically converging (7') portion of the passage (7; 7',7") via ducts (12) which converge at an acute angle from a co-axial annular chamber (11) around the passage connected (3) to the air supply. The narrow end of the conical portion (7') connects with a constant-diameter (7") discharge tube (5). Upstream of the air exit orifices of the ducts (12), the passage is provided with radial bores (13) to admit outside air. Introducing glass wool etc. into cavity wall by compressed air-driven ejector. The entry of the compressed air in the conical portion (7') of the passage rather than at its transition to the constant-diameter portion (7") and the sharper convergence of the duct (12) axes than that of the portion (7') eliminates the risk of clogging and tease the material apart in the desired fibrous structure.

Description

r ____ N / 30.66 4-Jb / cs -¾¾¾

Device for supplying insulating material, such as glass wool or rock wool, in the cavity of a cavity wall.

The invention relates to a device for supplying insulating material, such as glass wool or rock wool, in the cavity of a cavity wall, carried out with an ejector, which is on the one hand on a supply pipe for the insulation material and on the other hand on a supply pipe for compressed air can be connected, the insulating material being drawn in from the supply reservoir into the ejector only by the underpressure generated by this compressed air in the ejector, and the ejector comprising a housing to be used as a handle, to which a short exhaust pipe piece is connected, of from which the insulating material is blown into the cavity, while in the ejector and the exhaust pipe piece a central channel is formed, to which the supply pipe of the insulating material can be connected on the side remote from the exhaust pipe piece and that with a first, in the direction towards the exhaust pipe piece to obtain a smaller cross section, at least approximately conical section to which a second section with approximately the same diameter connects, wherein the compressed air supply line is connectable to a ring channel formed in the housing, the center line of which coincides with the center line of the central channel and to which a number of compressed air supply channels connect, which open out evenly over the circumference into the central channel and which enclose an acute angle with the longitudinal axis of this central channel.

In a known embodiment of such a device for supplying insulating material in the cavity of a cavity wall, the compressed air supply channels open out at the transition of the at least approximately conical part of the central channel in the portion of this central channel with approximately constant diameter.

With this known device, the drawback arises that the insulating material, which has a flake structure when the ejector is reached, can cause blockages as it passes the conically narrowing part of the central channel, as a result of which the supply of the iso- 8200536 i - 2 - Insulation material in the cavity is interrupted and time-consuming work must be carried out before the supply of the insulation material can be resumed.

The object of the invention is to provide a device of the type mentioned in the preamble, wherein this drawback is effectively eliminated.

To this end, this device according to the invention is characterized in that the compressed air supply channels open into the conical part of the central channel, while upstream of the outlets of these compressed air supply channels, ambient air supply channels communicating with the outside air open into the central channel.

Surprisingly, it has been found that this arrangement of the outlet of the compressed air supply ducts effectively prevents blockages of the insulating material in the conical part of the central duct. The compressed air supply via the compressed air supply channels creates a negative pressure within a fictitious cone, the descriptive lines of which are in line with the compressed air supply channels. This underpressure causes the suction effect on the glass or rock wool material. This negative pressure is, for example, 0.2 atm. In addition, the compressed air, which, for example, has a pressure of 6 ato, exerts a compressive force on the suctioned insulating material, as a result of which this is assisted, as it were, to pass through the conical part of the central channel.

The effect exerted by the compressed air on the glass or rock wool material supplied with a flake structure results in the insulation material obtaining a fiber structure, which makes this material exceptionally suitable for being fed into the cavity wall.

Since it may occur that insufficient air is available in the part of the central duct located behind the outlets of the compressed air supply ducts via the supply pipe of the insulating material, as a result of which the supply speed of the insulating material would be slowed down, mouths upstream of the outlets of the compressed air supply channels, the ambient air supply channels in the central channel that communicate with the outside air. Secondary air can be drawn into the single channel via these ambient air supply channels, keeping the air velocity in the negative pressure section of the ejector sufficient to pass the insulating material through the conical section of the central channel at the correct speed. .

The centerlines of. the compressed air supply channels on a fictitious conical surface, the top angle of which is greater than that of the conical surface, of which the conical part of the central channel forms part.

Around the underpressure zone there is therefore an annular zone in which overpressure prevails.

Preferably, the compressed air supply channels open out in the middle region of the conical part of the central channel. The most favorable results were obtained in experiments if the distances from the outlets of the 15 compressed air supply ducts in the central duct to the narrowest and widest cross section of the conical part of this central duct are approximately 1: 2.

According to a particularly simple constructional embodiment of the device according to the invention, the ejector comprises an insert fixed in the housing, which forms the ring channel with the housing and in which the compressed air supply channels are arranged and the ambient air supply channels are formed outside the housing.

Furthermore, the exhaust pipe piece can extend to the narrowest cross-section of the conical part of the central channel and itself be designed with a constant internal diameter.

The invention will be explained below with reference to the drawing, which shows an exemplary embodiment of an apparatus according to the invention for supplying insulating material, such as glass wool or rock wool, in the cavity of a cavity wall in cross section.

The drawing shows an exemplary embodiment of a device for supplying insulating material, such as glass wool or rock wool, in the cavity of a cavity wall.

This device is designed with an ejector 1, which is connected on the one hand to a supply pipe for the insulating material on the rear side 2 and on the other hand to a supply pipe for compressed air with the threaded hole connection 3.

8200536 - 4 - ... ...,. \

The ejector 1 comprises a housing 4 to be used as a handle, to which a short exhaust pipe piece 5 is connected. To this end, this exhaust pipe piece 5 has an externally threaded end collar 6, which meshes with a threaded hole in the housing 4.

The insulating material, which is drawn in into the ejector 1 by the compressed air generated by the compressed air in the ejector 1, is blown into the cavity of a cavity wall via this outlet pipe piece 5.

A central channel 7 is formed in the ejector 1 and the exhaust pipe piece 5, which is formed with a first conical part 7 ', which has a smaller cross section towards the exhaust pipe piece 5, on which a second part 7'1 with approximately constant diameter.

As can be seen from the drawing, the exhaust pipe piece 5 extends to the narrowest cross-section of the conical part 7 * of the central channel 7 and this exhaust pipe piece 5 itself forms the part 7'1 of the central channel 7 with approximately the same diameter.

The ejector 1 comprises an insert 8 inserted into the housing 4, which is secured therein by means of a locking screw 9. This insert 8 has a central, conically narrowing cavity 10, which forms about 2/3 of the conical portion 7 'of the central channel 7.

The insert 8 forms with the housing 1 a ring channel 11, which is connected to the compressed air supply line. The centerline of the ring channel 11 coincides with the centerline of the central channel 7.

Connected to the ring channel 11 are a number of compressed air supply channels 12, which are formed in the insert 8 and open out evenly over the circumference into the central channel 7 and enclose an acute angle with the longitudinal axis of the central channel 7, which larger is then the acute angle which the descriptive lines of the conical section 7 * enclose with this longitudinal axis.

According to the invention, the compressed air supply channels 12 open into the conical portion 7 'of the central channel 7.

In the exemplary embodiment shown in the drawing, the distances from the outlets of the compressed air supply ducts 12 in the central duct 7 to the narrowest and widest cross section of the conical section 7 'are shown in the drawing. of this central channel 7 is approximately 1: 2.

By supplying compressed air with a pressure of, for example, 6 ato via the compressed air supply channels 12, an underpressure of, for example, 0.2 atm is generated in a conical section within the central channel 7, while an overpressure prevails outside this conical section. As a result of this under-pressure, insulating material is sucked in from a storage reservoir via the supply pipe connected to the rear side 2 of the ejector 1. Due to the suction effect exerted on the insulating material, in combination with the entraining action exerted in the conical part 7 'of the central channel 7 on the insulating material 15 by the compressed air leaving the compressed air supply channels 12, a flow through of the conical part 7 " of the central channel 7 without the occurrence of blockages.

Ambient air supply channels 13, which connect the central channel 7 to the outside air, and which are formed in the insert 8 outside the housing 4, ensure that sufficient air can always enter the central channel 7 backwards from the outlets of the compressed air supply channels 12.

As a result, an excellent transport of the insulating material through the ejector 1 is obtained, while this material in the ejector 1 further obtains the extremely favorable fiber structure.

The invention is not limited to the exemplary embodiment shown in drawing 30, which can be varied in various ways within the scope of the invention.

8200536

Claims (7)

1. Device for supplying insulating material, such as glass wool or rock wool, in the cavity of a cavity wall, provided with an ejector, which can be connected on the one hand to a supply pipe for the insulating material and, on the other hand, to a supply pipe 5 for compressed air, the insulating material being exclusively by the underpressure generated by this compressed air in the ejector is drawn into the ejector from a storage reservoir and wherein said ejector comprises a housing which can be used as a handle, to which a short exhaust pipe piece 10 is connected, from which the insulating material is blown into the cavity, while in the ejector and the exhaust pipe piece a central channel is formed, on which the supply pipe of the insulating material can be connected to the side remote from the exhaust pipe piece and that with a first section, at least roughly conical, towards the exhaust pipe piece part is performed, on which a second part with an approximately constant diameter, the compressed air supply line being connectable to a ring channel formed in the housing, the center line of which coincides with the center line of the central channel and to which a number of compressed air supply channels connect, which are distributed evenly over the circumference in the central duct and enclosing an acute angle to the longitudinal axis of this central duct, characterized in that the 25 compressed air supply ducts open into the conical part of the central duct, while upstream of the outlets of these compressed air supply ducts, with the outside air open ambient air supply ducts into the central duct. Device according to claim 1, characterized in that the axes of the compressed air supply channels lie on a fictitious conical surface, the top angle of which is greater than that of the conical surface, of which the conical part of the central channel forms part. Device according to claim 1 or 2, characterized in that the compressed air supply ducts open out in the central region of the conical part of the central duct. 8200536 V - 7 - -ff. 4. Device according to claim 3, characterized in that the distances from the outlets of the compressed air supply ducts in the central duct to the narrowest and widest cross-section of the conical part of this central duct are approximately 1: 2 . 5. Device as claimed in any of the foregoing claims / characterized in that the ejector comprises an insert mounted in the housing / which forms the ring channel with the housing and in which the compressed air supply channels are arranged and the ambient air supply channels are formed outside the housing. 6. Device as claimed in any of the foregoing claims / characterized in that the exhaust pipe section extends to the narrowest cross-section of the conical part of the central channel and is itself designed with a constant internal diameter. 7. Device according to any one of the preceding claims, characterized in that the outlet pipe piece has an externally threaded end collar which meshes with a threaded hole in the housing. 8200536