RU2485547C1 - Coordinate gas-filled detector - Google Patents

Abstract

FIELD: measurement equipment.

SUBSTANCE: coordinate gas-filled detector comprises thin-walled drift tubes - straw. The straw is combined into modules, which represent rigid planar structures of one straw layer. Two modules with identical area of thickness equal to straw diameter are combined with a shift to each other to a straw radius into a single structural unit with distribution tubular gas collectors, elements of high-voltage supply of straw and elements of transmission of registered signals to external reading electronics.

EFFECT: registration of particles with high coordinate and angular resolution with a detector of large area.

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Description

The invention relates to coordinate gas-filled radiation detectors and can be used in the field of experimental physics [1, 2, 3, 4], for work in high-intensity flows of charged particles, as well as in geology [5, 6, 7], archeology [8, 9 ] and for radiographic monitoring of large-scale building structures [10, 11]. Using the angular distribution of space muons, it is possible to carry out tomographic studies of large-scale objects with muon detectors with high angular resolution [12, 13, 14, 15].

At present, gas-filled coordinate muon detectors based on metal drift tubes with a diameter of 3 cm or more, operating at a gas filling pressure of several atmospheres, are widely used [16]. The main disadvantage of such detectors is the limitation of their track efficiency with increasing particle multiplicity, which is determined by the large size of the sensitive region of the detecting elements of the detector (equal to the product of the diameter of the tube by the length) and the long collection time of ionization electrons. The space charge from slow positive ions distorts the electric field, significantly worsening the detector parameters. The decrease in the sensitive area and the time of collection of electrons by reducing the diameter of metal tubes of large length is limited by their poor uniformity in length and deterioration in the accuracy of the diameters.

Coordinate detectors based on thin-walled drift tubes (straws) are widely used in experiments on accelerators [1, 2, 3, 4]. Detectors consist of a series of planes containing straws with a diameter usually from 4 mm to 10 mm and a length of up to ~ 400 cm [1, 3, 4]. The high accuracy of the diameters and cylindricality of the straws, independent of their length, determine the uniformity of the detecting elements, which is essential for multichannel detectors. Straws operate at a gas mixture pressure close to one atmosphere, however, the possibility of straw performance at pressures up to 5 atmospheres has been shown [17]. A typical average spatial resolution (σ) along the straw radius is about 170 microns, and at a pressure of 3-4 atmospheres it can be improved to 40 microns [18, 19, 20]. With increasing gas pressure, an increase in diameter and length is observed, changing the straightness and anode-cathode distance along the straw length, which requires taking this into account when creating detectors. The use of straws of the required length and diameter from 4 to 15 mm for muon detectors in comparison with metal drift tubes can significantly reduce both the sensitive area of the detecting elements and the collection time of ionization electrons.

Closest to the proposed device is a two-layer detector of the COMPASS spectrometer [3, 4] with a straw length of 360 cm, a diameter of 6 mm and 10 mm, adopted as a prototype. The straws of each layer are glued together by a narrow longitudinal glue seam while maintaining their cylindricality (20 microns) and straightness (about 100 microns). The chambers are purged with a gas mixture at a filling pressure close to 1 atmosphere. Sealed gas distribution manifolds common for two layers are located at the two ends of the straw and contain the output parts of the straw with elements for fixing the anodes, as well as parts of the readout or matching boards. The detector feature is a large sensitive area (~ 9 m ² ) and radiation thickness less than 0.15% X ₀ (excluding gas). The detectors have a good speed, determined by the maximum collection time of ionization electrons (~ 110 nsec), and a spatial resolution of about 190 microns. The disadvantages of the prototype are the difficulty of ensuring good sealing of gas collectors, the presence in their internal volume of materials is not always with high chemical purity, as well as the sensitivity of the straw film wall to moisture, which can lead to a change in their length, leading to a violation of the alignment of the anodes with cathodes. To prevent this, the outer surfaces of the straw layers are covered with a metallized film, the gap between which and the straw is blown with dry gas. The prototype does not have complete sealing, which leads to losses of the working gas mixture; changes in the linear dimensions of the straw due to daily changes in temperature and humidity of the environment do not provide registration of particles with the largest possible coordinate and angular resolution by a large-area detector.

The technical problem is solved by creating a coordinate gas-filled detector, including thin-walled drift tubes - straws, which are combined into modules, which are rigid planar structures of one layer of straws, while two modules with a thickness uniform in area equal to the diameter of the straws are combined with a radius shift between them straws in a single structural unit with distributive tubular gas collectors, high-voltage power supply straws and elements for transmitting recorded signals to an external readout electronics. All the component nodes of the module are capable of blowing the straw with gas filling from one to 4 atmospheres, gas manifolds installed at the ends of the straw are connected to the internal volume of each straw through openings in their walls and in the end sleeves by capillary tubes placed orthogonally to the plane module. Each layer of the module has 2 gas collectors on its outer side for gas inlet and outlet, and metal tubular gas collectors are elements of its frame. In this case, the gas collectors do not contain internal matter, and the readout and matching boards are connected to the anodes, bypassing the sealed gas volumes.

Figure 1 shows a block diagram of the installation of a gas collector on a straw module of the proposed detector. The modules contain a straw of one diameter, which can be from 4 mm to 15 mm with a straw length of up to 4 meters, and an equal number of recording channels in each layer (a multiple of eight). At the ends of the straw 1, tubular gas distribution gas collectors 2 are installed, connected to the internal volume of each straw through the holes in their walls and in the end sleeves 3, placed capillary tubes 4 orthogonally to the module plane 4. As a anode 5, a gilded tungsten wire with a diameter of 30 μm installed in the center of the straw with a tension of 70 grams and fixed in the elements of its fixation 6. The straws of the module are positioned with an accuracy of about 50 μm into a dense layer with a thickness equal to their diameter, and the compound is flooded m 7. A general view of a detector containing two identical modules is shown schematically in FIG. 2. Each module has two gas manifolds 2 on its outer side, providing gas inlet and outlet. At one end of the straws of each module, multilayer readout boards 8 are installed parallel to their plane, providing high-voltage voltage to the anodes and transmitting signals from them to the inputs of the amplifiers of the recording electronics. At the second end of the straw, matching RC chains (not visible in Fig. 2) are installed on a narrow matching board The connections of the internal volumes of the straw with gas tubular manifolds and the protruding parts of the inner sleeves 3 with the fixing elements 6 are sealed with a compound. Tubular metal collectors, as well as readout and matching boards, together with the metal bases supporting them, after combining the modules, are elements of the detector’s common frame orthogonal to the direction of the straw. As parallel to the direction of the straw, frame elements are used carbon-fiber or aluminum thin-walled profiles 9, installed along the extreme straws on each side of the module. The thickness of the sensitive area of the detector is equal to two straw diameters with an accuracy of +0.3 mm. A thin metallized film 10 is glued on the outer surfaces of the modules, which serves to protect against environmental humidity and is used as the electromagnetic screen of the detector. On each side of the module, to the height of the gas collectors exceeding its outer surface, plastic support tapes 11 are installed (coal / glass) 11 with a step determined depending on the length of the straw. The detector frame has mounting holes for combining it with similar detectors into a single detecting system. The detector operates as follows. Straws are blown with a working gas mixture at a fixed pressure of one to 4 atmospheres. Gas enters / exits the system through capillary tubes with the same gas resistance, into thick-walled tubular manifolds, which are the end parts of the detector frames. When particles pass through two modules, their coordinates in space are recorded by measuring the drift time of the ionization electrons closest to the anodes in the triggered straws. The anodes of the straws of each module are connected from one end to the readout boards and from the other to the matching boards, which are the end parts of the frame. The high voltage anode voltage is supplied through the readout boards. Charged particles crossing two modules combined into a single chamber ionize the gas in the formation, forming electrons moving to the anode and forming a signal. Signals from the anodes are transmitted through the boards to the multi-channel connectors installed on them and then to the recording electronics and are used to determine the coordinates of the particle trajectories in the plane of the modules. With increasing pressure, the number of electrons and the magnitude of the signal increase in multiples, increasing the probability and accuracy of event recording. The linear dimensions of thin-walled film tubes and modules as a whole do not change with increasing gas filling pressure, preserving the alignment of the anode-cathodes, which eliminates errors in determining the spatial coordinates of events. The magnitude of the maximum electron drift time (from the cathode to the anode) at a normal pressure of about 20 nsec per millimeter of straw radius, which determines the speed of the detector depending on their chosen radius. With increasing pressure, the drift velocity decreases and for straws with a diameter of 10 mm at a pressure of 3 atmospheres, the collection time increases to ~ 200 nsec. The radiation thickness of the module is less than one percent.

Technical result: large planar detectors with straws with diameters from 4 mm to 10 mm and with metal tubular gas collectors, which are also elements of the detector frames, have the ability to operate in the pressure range of their gas filling up to 4 atmospheres without changing the linear dimensions of the straws. Collectors do not contain internal matter, have high chemical purity and tightness. The supply of the anode voltage and the readout of signals, as well as the matching of the anodes, are carried out by appropriate boards completely located outside the gas volumes near the fixation of the anodes in the end elements of the straw, which reduces the size of the signal lines and, therefore, stray inductances and capacitances. The detector has a low mass and a close to 1 ratio of the total area to the sensitive. Overlapping large detection areas with identical detectors does not require massive support structures. The absence of a dependence of the linear dimensions of the straw on the climatic parameters of the environment and on the gas filling pressure ensures the stability of the detector characteristics with high uniformity in area. The increase in pressure helps to increase spatial resolution during registration of charged particles and increase the likelihood of registration of x-ray radiation.

Information sources

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Claims (3)

1. A gas-filled coordinate detector, including thin-walled drift tubes — straws, characterized in that the straws are combined into modules, which are rigid planar structures of one layer of straws, while two modules with a uniform thickness in thickness equal to the diameter of the straws are combined with a shift between themselves by radius of straws in a single structural unit with distribution tube gas collectors, high-voltage straw elements and elements for transmitting recorded signals to external readout electronics I am. 2. The detector according to claim 1, characterized in that all the component nodes of the module are capable of gas purging with filling from one to 4 atmospheres, while the gas manifolds installed at the ends of the straws are connected to the internal volume of each straw through openings in their walls and in the end sleeves, placed orthogonally to the plane of the module, by capillary tubes. 3. The detector according to claim 1, characterized in that each layer of the module has 2 gas collectors on its outer side for gas inlet and outlet, and metal tubular gas collectors are elements of its frame.

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