CS216229B2 - Ionization fire detector - Google Patents

Abstract

1430891 Ionisation detectors CERBERUS AG 17 April 1974 [17 April 1973] 16848/74 Heading H1D An ionization fire sensor 2 has an ionization chamber 10 with an ionizing radiation source 9 and electrodes 8, 11, so that the ion current changes in the presence of fire or smoke. Portions 4, 5 of the housing are separated by an annular slit 13 so formed as to deflect the flow of air through slit 13 to chamber 10 from its direct path. The portion 5 is removable for cleaning. Electrode 11 is an air-pervious grid or mesh preventing access to electrode 8. The sensor 2 is mounted on a portion 1. Air entering slit 13 is baffled by a wall 12 and passes through mesh electrode 11 into chamber 10, where it is ionized by radio-active material 9, e.g. americum 241. Current flowing between electrodes 8, 11 is detected by a circuit 14, which preferably includes an FET input transistor and is connected to an indicator lamp, such as an LED3. Optimum dimensions of the apparatus are given. The housing portions 4, 5 are made of non- conductive material, or preferably are of metal held at a voltage different from that of electrode 11 by a connection 11<SP>1</SP>. In a modification, Fig. 2, not shown, the housing (21) is made in one piece and is connected to a plate (26) so as to leave a substantially continuous annular gap between the parts.

Description

The present invention relates to an ionization fire detector having a housing surrounding an ionization chamber with two electrodes and a radioactive source in which the ion current is changed in the presence of smoke and flue gas in the air.

There are various requirements for ionizing fire detectors of this kind. It is important that it is as sensitive as possible, which means that the ion flow should change substantially even at the lowest concentration of smoke or flue gas in the air. This can be achieved, for example, by selecting a low field strength to control the transistor to which a control electrode is connected to one of the electrodes of the ionization chamber.

Since the known low voltage voltage ionisation fire detectors are relatively sensitive to air flow, it has proved necessary to slow down the speed of the air entering the ionization chamber by suitable braking means or by means of reversing the air flow direction. However, this means that the dust supplied by the incoming air can settle and settle in places where the air is blown by the said means. Accordingly, the respective areas of the fire detector housing contaminate relatively quickly, particularly around the inlet openings of the housing. It is therefore necessary to clean the cover frequently, which is labor intensive and expensive.

Furthermore, when opening the cover for cleaning, there is a risk that sensitive parts may be accidentally touched. In known low voltage ionization fire detectors that use a field-controlled transistor, contact with the electrode of the ionization chamber associated with the control electrode of the transistor can result in damage to the transistor. It has therefore proved necessary to protect the transistor from damage by suitable means, for example a protective switch. However, such a measure is complex and costly.

The purpose of the invention is to overcome these drawbacks and to provide an ionisation fire detector which is less polluting and which can be cleaned in a simple manner without the risk of damage to its components, while not detecting the sensitivity of the detector to the presence of smoke in the air.

The ionisation fire detector according to the invention fulfills this purpose, the inner electrode of the ionization chamber being connected to the control electrode of the field-controlled transistor, the counter electrode of the ionization chamber being formed by a grid surrounding the inner electrode and protecting it from damage, and the cover is at least partially removable. SUMMARY OF THE INVENTION The cover is provided with an annular gap for the entry of air into the ionization chamber, and a cylindrical or conical baffle wall is provided against the annular gap within the housing to change the direction of the incoming air and guide it along the counter electrode surface.

In one preferred embodiment, the annular gap is formed between the cylindrical or conical housing of the cover and its removable lid, on the inside of which a rectifying wall is provided.

In a second preferred embodiment, the annular gap is formed by a gap between the edge of the integral one-piece housing and the surface of the support member to which the base plate of the ionization chamber is attached, the base plate forming a circumferential surface for the incoming air.

By creating an annular gap, and against the baffle wall thereto, the desired air flow and direction change are achieved. As a result, relatively heavy dust particles settle at readily accessible locations on the inner wall of the protective cover or on the removable lid so that cleaning is easy and there is no risk of damage to the inner electrode, which is additionally protected by the counter electrode. In this way, only tangentially directed air with substantially lighter smoke particles flows through the grating from which the counterelectrode is formed inside the ionization chamber.

It has been shown that in order to achieve a high sensitivity of the detector and the most effective separation of dust particles, it is advantageous to have a height of the baffle wall at least twice the width of the annular gap, the maximum distance between the baffle wall and the cylindrical or conical wall the width of the annular gap and the depth of the annular gap is at least half in proportion to its width.

Further, an embodiment is provided in which a removable backing plate of insulating material is provided in the housing housing to which both electrodes of the ionization chamber are attached.

The subject matter of the invention is apparent from the description and schematic drawing, in which an exemplary embodiment of the detector according to the invention is shown in axial section in FIG.

The ionisation fire detector of FIG. 1 consists of a base 1 and a detector 2 itself. The base 1 is provided with a lateral recess in which an alarm signal bulb 3, for example a light emitting diode, is accommodated.

The detector 2 is provided with a cover 21 formed by a cylindrical or slightly conical housing 4 with a lid 5. Between the housing 4 and the lid 5 there is an approximately 5 mm wide annular slot 13 for air inlet into the housing. On the inside of the lid 5 there is at least a 10 mm high cylindrical baffle wall 12 for inhibiting the incoming air and directing it inside the housing 4 along its inner wall.

The distance of the baffle wall 12 from the sleeve 4 may be greater or less than the width of the slot 13. It may not be constant, but may increase upwards, as is the case with the cylindrical baffle wall and the conical sleeve 4. This distance may also be upwards. For example, the wall 12 is conical and exhibits greater conicity than the sleeve 4. The lid 5 may project laterally beyond the lower outer edge of the sleeve 4.

Particularly advantageous air inlet parameters are achieved when the following conditions are met:

The height H of the wall 12 must be at least twice the width B of the slot 13;

the maximum distance A between the baffle wall 12 and the housing 4 must be at most twice the width B of the slot 13;

- the depth T of the slot 13 must be at least half that of the B-slot of the slot 13.

For example, at a slot width B of 13 - 3 mm, the height H of the wall 12 is 9.5 mm, the maximum distance A between wall 12 and the sleeve is 4 - 3.5 mm, and the depth T of the slot 13 - 5 mm.

The absolute values of the dimensions A, B, Η, T are not important. Only relative values Η, T and A in relation to the width B are relevant.

Inside the housing 21 there is a support plate 6 of insulating material on which other components are fixed. A metal pin 7 passes through the axial opening of the support plate 6, which carries on the underside of the support plate 6 a disc internal electrode 8 with a radioactive source 9, for example Americium 241. On the underside of the support plate 6 a counterelectrode 11 is formed. holes that surround the inner electrode 8 and protect it from contact. The inner electrode 8 and the counter electrode 11 form an ionization chamber 10 below the carrier plate 6. Above the carrier plate 6, a known electrical circuit may be provided to evaluate changes in the ionic current of the ionization chamber 10, which may include a reference ionization chamber isolated from the external atmosphere. connected in series with the ionization chamber 10.

In order to protect the interior of the detector and the ionization chamber 10 from dust, it is expedient for the cover 21 to be metallic and to provide electrical potential to the housing 4 and the lid 5

Claims (5)

An ionisation fire detector having a housing surrounding an ionization chamber having two electrodes and a radioactive ion source whose current changes in the presence of smoke and flue gas, the internal electrode of the ionisation chamber being connected to the control electrode of a field-controlled transistor; and the cover is at least different from the potential of the lattice counter electrode 11, or the cover 21 can be made of a non-conductive material. The dust particles are deposited by electrostatic charge of the material on the housing 21 and are not introduced into the ionization chamber 10. The lid 5 of the housing 21 is - preferably removable from the housing 4, to facilitate cleaning. The described solution of the ionisation fire detector achieves that the air entering through the annular gap 13 is braked immediately behind it by the deflection wall 12 and its direction changes to vertical so that it flows further along the surface of the counter electrode grating 11. heavy dust particles, while substantially lighter smoke particles continue to flow. As a result, the airborne dust particles preferably deposit on the inner wall of the housing 21 or near the slot 13 and do not enter the ionization chamber 10 while the smoke enters it substantially without obstruction. By removing the entire protective cover 21 or only the lid 5, the deposited dust can be easily removed and the fire detector can be cleaned in a simple manner. The lattice counter electrode 11 repels dust on the one hand and protects the inner electrode 8 from damage when the cover 4 or the cover 5 is removed. The inner electrode 8 is connected to the control electrode of the field-controlled transistor so that there is no risk of transistor damage during this gentle cleaning. Giant. 2 illustrates another exemplary embodiment of an ionization fire detector according to the invention. In this embodiment, the integral one-piece housing 21 is separated by an annular slot 22 from the support member 27. The ionization chamber 20 is also provided with an internal electrode 23 and a counter electrode 24 formed as a fine lattice. The cover 21 is removable. The peripheral baffle wall 25 of the base plate 26 of insulating material serves as a means of braking and reversing the air entering the housing 21 through the slot 22. Also in this embodiment, the incoming air is braked and its direction is changed, with the incoming dust depositing on the inner wall of the housing 21. Here again, the mesh counter electrode 24 repels the dust without hindering the flow and protects the inner electrode 23. BACKGROUND OF THE INVENTION partially removable, characterized in that the cover [21] is provided with an annular slot (13, 22) for air inlet into the ionization chamber (10, 20), wherein a cylindrical slot (13, 22) is provided with a cylindrical slot or a conical baffle wall (12, 25) for changing the direction of the incoming air and guiding it along the counter electrode surface (11, 24). Ionisation fire detector according to Claim 1, characterized in that the annular gap (13, 22) is formed between the cylindrical or conical housing (4) of the housing (21) and its removable cover (5), the inside of which is provided with rectifiers wall (12). Ionisation fire detector according to claim 1, characterized in that the annular gap (22) is formed by a gap between the edge of the integral one-piece housing (21) and the surface of the carrier (27) to which the base plate (26) of the ionization chamber is attached. (20), wherein the base plate (26) forms with its peripheral surface a baffle wall (25 -) 'for the incoming air. 4. The ionisation fire detector according to claim 1, 2 or 3, characterized in that the height (Ή) - of the wall guide [12, 25-] is at least twice the width - (B) of the annular slot - (13, 22). , the maximum distance - (A) between the baffle wall (12, 25 -) and - the cylindrical or conical wall - of the cover (21) is at most twice the width (B) ^{1 of the} annular slot (13, 22) and - depth ( T) the annular slot (13, 22) is at least half in proportion to its width (B). Ionisation fire detector according to Claims 2 and 4, characterized in that a removable support plate (6) of insulating material to which both electrodes (8) are attached is provided in the housing (4) of the cover (21). , 11) an ionization chamber (10).