DE3930798A1 - GAS DETECTOR - Google Patents

Abstract

A gas meter for cumulatively displaying the amount of gas consumed includes a rotary member (40) comprising an integrally-molded resin-bonded magnet in which a plurality of N and S poles are arranged alternately. The resin-bonded magnet comprises ferrite rare earth or alnico alloy magnetic powder, and a thermoplastic resin, a thermosetting resin or a rubber binder. The gas meter includes a magnetic sensor (50) facing the N and S poles successively in accordance with the rotation of the rotary member to produce pulse signals. The magnetic sensor is formed from a reed switch, a Hall element, a Hall IC or a magnetic reluctance element. The signals produced in the sensor are transmitted to a counter portion in which the amount of the gas consumed is displayed. <IMAGE>

Description

The invention relates to a gas meter for cumulative Displays the amount of gas used.

Typically, as shown in Fig. 1, a cumulative display type gas meter is known which records the amount of gas consumed by a reciprocating motion generated by a measuring film (not shown) in a measuring section 100 on a crank section 110 into a Rotational movement is converted that a counter section (an electronic counter) 120 is operated by the rotary movement. This known gas meter is shown, for example, in Japanese Patent Laid-Open No. 62-1 53 713.

In the known gas measuring device, the crank section 110 and a dome-like rotary member 140 , to which the rotary movement generated on the crank section 110 is transmitted, are provided in an upper housing 130 . A plurality of magnets 150 are attached in an outer circumferential groove 141 of the rotary member 140 such that each N-pole and each S-pole of the magnets 150 are arranged alternately. In addition, a magnetic resistance element 160 is arranged in a position of the counter portion 120 which is opposed to a plurality of magnets 150 in succession in accordance with the rotation of the rotary member 140 .

When the reciprocation generated by the measuring film in the measuring section 100 is converted into the rotating movement on the crank section 110 which causes the rotating member 140 to rotate, the magnetic resistance element 160 opposes the plurality of magnets 150 , due to the magnetic action of the magnets causing 150 resistance changes. Thereafter, pulse signals are transmitted from the magnetic resistance element 160 to the number section 120 , and a gas flow strength is then cumulatively displayed on a liquid crystal display device 170 provided in the counter section 120 .

In the gas meter described above, the same number of pulse signals as the number of the magnets 150 mounted in the rotating member 140 are transmitted to the counter section 120 when the rotating member 140 is subjected to a single rotation. That is, when a rotation of the rotary member 140 corresponds to 0.7 l of the gas flow rate, the gas flow rate can be measured or determined by a unit of 0.7 / (the number of magnets) · l. In this type of gas meter, the measurement accuracy is improved with the increase in the number of poles.

As mentioned above, the number of the magnets 150 is arranged in the outer circumferential groove 141 of the rotary member 140 such that each N-pole and each S-pole of the magnets 150 are arranged one after the other; thus the number of magnets 150 or magnetic poles must be limited. As a result, the gas flow rate cannot be measured with high accuracy using the known gas measuring device.

In addition, since both magnetic poles (N-poles, S-poles) of the magnets 150 on the outer circumferential groove 141 of the rotary member 140 have to be reversed and alternately attached, the number of operations in the assembly must be increased, so that the production becomes rather expensive .

Furthermore, it is difficult because of the production cost this increased effort in the manufacturing process to reduce.

The invention is therefore based on the object Gas meter to create a gas flow rate with high Accuracy can measure that without much difficulty produced and at reduced production costs can be realized.

This object is achieved by a gas measuring device solved for cumulative display of gas flow strength, the comprises: a measuring section; one in the measuring section provided measuring film, the measuring film of the gas stream is reciprocated, a crank section to Transform the back and forth movement of the measuring film in one Rotary motion, a rotary member by which by the Crank portion transmitted rotary motion is rotated the rotating member being an integrally molded resin-bonded magnet in which a variety of N and S poles are arranged alternately, one Magnetic sensor, which is arranged in a place that opposite the N and S poles of the resin-bonded magnet successively according to the rotation of the rotary member lies in order to generate pulse signals, and one Counter section that transmits from the magnetic sensor Signals is actuated to indicate the gas flow rate.  

According to the gas meter of the invention, the by Measuring film in the measuring section caused reciprocation transformed into the rotary motion on the crank portion. The Rotary motion is transmitted to the rotating element. Then it will be the rotating member rotated so that the N and S poles of the Rotary member of the magnetic sensor one after the other and alternately are opposite, the generated in the magnetic sensor Signals are transmitted to the counter section. As soon as the signals have reached the counter section, the Gas flow strength displayed cumulatively.

Since the rotary link is the integrally molded, resin-bonded Magnet includes a variety of N and S poles are arranged alternately, in this case it is easier to increase the number of poles in the rotating member increase. Since the resin-bonded magnet with the Variety of N and S poles made in one mold can be compared to the usual rotating element simpler, the rotary member according to the invention, in which one Variety of magnets on the outer circumference of the Rotary member are attached to manufacture.

In the gas measuring device according to the invention, the resin-bonded magnet can furthermore be formed from a magnetic powder as a filler and binder for binding the magnetic powder. As the magnetic powder, a ferrite type magnetic powder such as Ba ferrite and Sr ferrite, etc. can be used. Furthermore, a magnetic powder based on rare earth metals, such as Sm ₁ Co ₅ , Sm ₂ CO ₁₇ , Nd-Fe-B and R-CO (R = Y, Ce, Pr, Pt, La) and / or a Magnetic powder based on an Alnico alloy can be used. On the other hand, a thermoplastic such as polyamide, polyacetal, polyethylene, polypropylene, polyphenylene sulfide and fluororesin, a thermosetting resin such as epoxy resin, phenolic resin or urea resin, or a rubber such as natural rubber, silicone rubber or acrylonitrile-butadiene rubber can be used as the binder. Optionally, an epoxy resin coating or an electrostatic coating can be applied to the surface of the plastic magnet.

Furthermore, the gas measuring device according to the invention Binder to form the resin bonded magnet have, which is made of a material with an excellent Has corrosion resistance to the gas to be measured.

In this case, the advantage is that the Rotary member is not corroded by the gas to be measured.

These and other tasks, features and benefits of present invention will become apparent from the following Description of the preferred embodiments in Connection with the following drawings described. Show it:

Fig. 1 is a partially sectional side view of a Gasmeßgerätes according to the prior art,

FIGS. 2 to 4 (d) an embodiment of a gas meter according to the present invention, where

Fig. 2 is an enlarged and partially sectioned front view of a gas meter according to the present invention,

Fig. 3 is a partially sectioned side view of the gas meter shown in FIG. 2, and

Fig. 4 (a) to 4 (d) are explanatory drawings of the arrangement relationships between a rotary member and a magnetic sensor.

The following is an embodiment of the present Invention described with reference to the drawings.

Fig. 2 is an enlarged and partially sectioned front view of an embodiment of a gas meter according to the invention. Fig. 3 is a partially sectioned side view of the gas meter according to Fig. 2. Shown here are a lower housing 10 which forms a gas measuring chamber and an upper housing 20 which is provided with a gas measuring inlet 21 and a gas outlet 22 , both with the Gas measuring chamber are connected.

A pair of film plates (measuring films) 11 are arranged in the lower housing 10 . The film plates 11 repeat their reciprocating operations due to a gas flowing through the gas inlet 21 into the measuring chamber and from there through the gas outlet 22 . A counter portion 30 is provided on the front of the upper case 20 . Provided in the upper housing 20 is a crank 25 which is equipped with joints 23 , 24 for coupling with a vane shaft (not shown) which is driven by the reciprocating rotary movement of the film plates 11 .

The crank 25 acts to convert the reciprocating motion of the vane shaft to a rotating motion in one direction. With the crank 25 , a rotary member 40 is connected, which comprises an integrally molded, resin-bonded magnet, in which a plurality of N and S poles of magnets are arranged alternately. Furthermore, a magnetic sensor 50 is arranged in the counter section 30 at a point at which the magnetic sensor 50 can face the magnetic poles (N poles, S poles) of the rotary member 40 one after the other.

The resin-bonded magnet that forms the rotating member 40 is formed from a magnetic powder that is hardened with a binder such as a thermoplastic, a thermosetting resin or rubber. Optionally, an epoxy coating or an electrostatic coating can be attached to the outer surface of the molded plastic magnets. The number of magnetic poles of the resin bonded magnet can be, for example, 8 or 16 (see Figs. 4 (a) to 4 (d)).

Examples of preferred magnetic powders include a ferrite type magnetic powder such as Ba ferrite (barium ferrite) or Sr ferrite (strontium ferrite). A magnetic powder based on rare metals, such as Sm ₁ Co ₅ , Sm ₂ Co ₁₇ , Nd-Fe-B or R-Co type (R = Y, Ce, Pr, Pt, La); Magnetic powder based on an Alnico alloy; and magnetic powder such as MnBi, MnAl, Vicalloy.

Examples of thermoplastics include polyamide, Polyacetal, polyethylene, polypropylene, fluororesin (Polytetrafluoroethylene, polychlorotrifluoroethylene, Polyvinylidene fluoride) and polyphenylene sulfide.

Examples of the thermosetting resin include epoxy resin, Phenolic resin, urea resin, melamine resin and diallyl phthalate a.  

Examples of the rubber relate to natural rubber, Silicone rubber, acrylonitrile butadiene rubber, Styrene-butadiene rubber, polyisoprene rubber and Cis polybutadiene rubber.

Regarding the corrosion resistance against the one to be measured For example, gas is mostly a thermoplastic Preferred polyacetal, followed by polyamideimide, polyamide, Fluorine rubber, polyvinylidene chloride, ionomer, Polypropylene and polyethylene, in that order. Under the thermosetting resins is further that most preferred epoxy resin followed by phenolic resin, Urea resin, melamine resin, diallyl phthalate, in this Sequence. After all, is under the rubbers Styrene-butadiene rubber the most preferred followed of polyisoprene rubber and cis-polybutadiene rubber, in this order.

In this case, by the way, a corresponding amount of Additives such as a plasticizer press-relieving additive or an adhesion promoter to that resin bonded magnet can be added.

A reed switch, a Hall element, a Hall IC or a magnetic resistance element can also be used as the magnetic sensor 50 .

In the case where a reed switch is used as the magnetic sensor 50 when the magnetic pole approaches it, tongues of the reed switch (tongue portions) formed by a magnetic body are magnetized. The removed portions of the tabs are then pulled and come into contact with each other, with the switch being switched to an ON state. On the other hand, when the magnetic pole moves away from the reed switch, the force pulling the tongues towards each other is weakened and the tongues are then separated from each other by the spring return force present in the tongues themselves, the switch coming into an OFF state.

When using the reed switch as the magnetic sensor 50 , the switch is arranged on the rotary member 40 , as shown in FIGS . 4 (a), 4 (b), for example. In Fig. 4 (a), the reed switch 50 is arranged in the radial direction of the rotary member 40 , while in Fig. 4 (b) it is arranged in the axial direction of the rotary member.

If one tongue of the switch faces the N pole and the other tongue faces the S pole, both tongues are pulled towards each other and the switch then comes into the ON state. Thereafter, according to the rotation of the rotary member 40 from the above-mentioned position, the tensile force (magnetic force) is gradually weakened until one tongue faces the S pole and the other the N pole. In this state, the spring return force of the tongues acts on the tongues, so that the switch goes into the OFF state. The switch then returns to the ON state when one tongue faces the S pole and the other tongue faces the N pole. Accordingly, during a rotation of the rotary member 40, the same number of pulses as the number of magnetic poles are output from the reed switch and transmitted to the counter section 30 . In this state, however, the number of poles of the resin bonded magnet is limited to eight poles because the reed switch cannot be formed in a smaller size.

When equipped with the Hall element or the Hall IC becomes a Hall voltage in the vertical direction  according to the directions of the current and the magnetic field generated when a magnetic field in the vertical direction corresponding to a flow that flows through it, works.

When using the Hall element or the Hall IC as the magnetic sensor 50 , it is arranged on the rotary member 40 , as shown, for example, in FIGS . 4 (c), 4 (d). In Fig. 4 (c), the Hall element or the Hall IC is arranged in the radial direction of the rotary member 40 , while in Fig. 4 (d) the Hall element or the Hall IC is arranged in the axial direction of the rotary member 40 . In this case, when the Hall element or the Hall IC facing the N pole then the subsequent S pole facing the rotating movement of the rotary member 40 , the direction of the magnetic field which is against the Hall element or the Hall IC acts, changed so that the Hall voltage V _{H is} also changed, for example from + V _H to - V _H.

Accordingly, during a rotation of the rotary member 40, the pulse signals, the number of which is half the number of the magnetic poles, are output from the Hall element or the Hall IC, and then transmitted to the counter section 30 . In this case, it is possible to set the number of poles of the resin-bonded magnet to 16.

With a magnetic resistance element, the further the resistance of the same is a maximum if the Direction of current flowing through the element and the Direction of the magnetic field (lines of magnetic force) become parallel to each other because there is a minimum if these directions are vertical to each other.  

In the case where the magnetic resistance element is used as the magnetic sensor 50 , the element is arranged with respect to the rotating member 40 in the same manner as the Hall element or the like (see Figs. 4 (c) and 4 (d)) . Accordingly, the pulse signals, the number of which corresponds to that of the magnetic poles, are output during a rotation of the rotary member. When a bias magnet that generates a bias magnetic field and shifts the strength of the magnetic field is used with the magnetic resistance element, pulse signals the number of which is half the number of magnetic poles are output and transmitted to the counter section 30 . As with the Hall element or the Hall IC, the magnetic resistance element is smaller than the reed switch, so that it is possible to set the number of poles of the resin bonded magnet to 16.

The counter section 30 includes an electronic counter which is actuated by the pulse signals of the magnetic sensor 50 in order to enable the cumulative display of the gas flow strength. A liquid crystal display 60 is arranged in the counter 30 to ensure the cumulative display of the gas flow rate.

According to the above-mentioned embodiment, the vane shaft causes its reciprocating rotary motion when the film plates 11 repeats their reciprocating motion due to the gas flow over the gas inlet 21 to the outlet 22 through the measuring chamber. The reciprocating motion of the vane shaft is then converted into the rotating motion in one direction on the crank portion 25 to thereby rotate the rotating member. Upon rotation of the rotary member 40, the pulse signals from the magnetic sensor 50 are output to the counter section 30, the counter portion 30 is pressed thereon, and the gas current cumulative display liquid crystal display 60 at the after.

In this embodiment, although the number of magnetic poles is increased, the manufacturing process does not become difficult since the resin bonded magnet that constitutes the rotating member 40 is integrally formed by injection molding or compression molding. Accordingly, it is also possible to increase the number of magnetic poles and to carry out measurement with high accuracy without problems. Furthermore, according to the rotary member 40 of the present invention, the number of steps in the manufacturing process can be reduced considerably compared to the conventional process in which a plurality of magnets are arranged in a ring shape. Furthermore, it is possible to fix a shaft 41 to the rotary member 40 by inserting it in a mold for casting the rotary member 40 in advance. In addition, the treatment of the rotary member 40 including the resin-bonded magnet is simplified because it is not as fragile as a magnet made by sintering the magnetic powder together.

When an electrostatic or epoxy resin coating is applied to the surface of the rotary member 40 , the corrosion resistance of the rotary member to a gas to be measured is improved.

If polyacetal as thermoplastic, epoxy resin as thermosetting resin or styrene-butadiene rubber as Rubber for the binder of the resin-bound magenta the magnet is used for a long time not corroded, so the corrosion resistance continues is improved.  

In summary, the gas flow rate can be high Accuracy measured and the gas meter in simpler Way to be manufactured at low cost since that Rotating member an integrally molded, resin-bonded magnet in which a plurality of N and S poles of Magnets are arranged alternately, and further the Magnetic sensor is provided in the position in which the Sensor the N and S poles one after the other by rotating the Rotary member can be opposite. According to the gas meter the invention is an additional advantage to the above mentioned advantages in that the rotary member of the measuring gas does not corrode over a long period of time is because an epoxy resin covering or electrostatic covering is attached to the rotary member.

Various changes are due to the teaching of the present invention possible to those skilled in the art without Deviate scope of protection.

Claims (11)

1. A gas measuring device for cumulatively displaying the gas flow strength, comprising:

• - a measuring section;
• - a measuring section provided in the measuring film (11), wherein the measuring film (11) from the gas stream and is reciprocated back;
• - A crank section for converting the back and forth movement of the measuring film ( 11 ) in a rotary movement;
• a rotating member ( 40 ) rotated by the rotational movement transmitted from the crank portion, the rotating member ( 40 ) having an integrally molded resin-bonded magnet in which a plurality of N and S poles are alternately arranged;
• - A magnetic sensor ( 50 ) which is arranged at a position which is opposite to the N and S poles of the resin-bonded magnet successively according to the rotation of the rotary member ( 40 ) to thereby generate pulse signals; and
• a counter section which is actuated by signals transmitted by the magnetic sensor to indicate the gas flow rate.

2. Gas meter according to claim 1, characterized in that the resin-bonded magnet of the rotary member ( 40 ) comprises a magnetic powder as a filler and a binder for binding the magnetic powder. 3. Gas meter according to claim 2, characterized in that that the magnetic powder is a magnetic powder from Ferrite type, such as Ba ferrite and Sr ferrite. 4. Gas meter according to claim 2, characterized in that the magnetic powder is a magnetic powder based on rare earth metals such as Sm ₁ Co ₅ , Sm ₂ Co ₁₇ , Nd-Fe-B and R-Co (R = Y, Ce , Pr, Pt, La). 5. Gas meter according to claim 2, characterized in that the magnetic powder is a magnetic powder on the Alnico alloy or magnetic base Powders such as MnBi, MnAl or Vicalloy. 6. Gas meter according to claim 2, characterized in that the binder is a thermoplastic, such as polyamide, Polyacetal, polyethylene, polypropylene, Is polyphenylene sulfide or fluororesin. 7. Gas meter according to claim 2, characterized in that that the binder is a thermosetting resin such as Is epoxy resin, phenolic resin or urea resin. 8. Gas meter according to claim 2, characterized in that the binder is a rubber, like natural Rubber, silicone rubber or Acrylonitrile butadiene rubber is. 9. Gas meter according to claim 2, characterized in that the resin-bound magnet further a lot of additives, such as a plasticizer, a pressure-relieving additive or an adhesion promoter includes.   10. Gas meter according to claim 1, characterized in that an epoxy resin coating or an electrostatic coating is attached to the resin-bound magnet of the rotary member ( 40 ). 11. Gas meter according to claim 1, characterized in that the magnetic sensor ( 50 ) comprises a reed switch, a Hall element, a Hall IC or a magnetic resistance element.