US3737844A - Method for detecting small particles in a tank and an apparatus for carrying out the same - Google Patents

Method for detecting small particles in a tank and an apparatus for carrying out the same Download PDF

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US3737844A
US3737844A US00192157A US3737844DA US3737844A US 3737844 A US3737844 A US 3737844A US 00192157 A US00192157 A US 00192157A US 3737844D A US3737844D A US 3737844DA US 3737844 A US3737844 A US 3737844A
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ultra
sonic
tank
transmitting
receiving means
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US00192157A
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T Yokoyama
T Kanda
Y Oshio
Y Hori
K Yazawa
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Chiyoda Corp
Chiyoda Chemical Engineering and Construction Co Ltd
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Chiyoda Chemical Engineering and Construction Co Ltd
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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B11/00Transmission systems employing sonic, ultrasonic or infrasonic waves

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  • the present invention relates to a method for detecting. small particles and a device for carrying out the same.
  • the small particles contained in the liquid in a reactor sink under the pull of gravity and accumulate at the bottom of the reactor as a fixed bed.
  • This fixed bed is converted to a fluidized bed by supplying a fluid at a predetermined rate of flow from the lower portion of the reactor.
  • this type of bed is used widely in carrying out chemical reaction, heating, cooling, drying etc..
  • I-Ieretofore known methods for measuring the small particles in a reactor employing the fluidized bed include those utilizing the difference in density of the materials in the reactor and those utilizing the change in electrostatic capacitance.
  • the conventional methods although it is possible to obtain relatively correct measurement when bubbles do not exist in the reactor, it is impossible to measure the small particles accurately when the fluid to be supplied to the reactor includes both gas and liquid phase materials because the gas phase materials, i.e., the bubbles are detected indistinguishably from the small particles.
  • a method is also known in which an ultrasonic transmitting apparatus and an ultra-sonic receiving apparatus are provided in the tank and the small particles are detected by measuring the time duration between transmission and reception of the ultra-sonic wave.
  • the thickness of the tank in the vicinity of the area where the measuring is performed is made thinner in order to minimize the absorption of the gamma rays by the tank.TAs a result, the ability of the tank to withstand high pressure is reduced thus increasing the danger of explosion of the tank.
  • One object of the present invention is to provide a method for easily detecting the existence of small particles in a fluidized bed containing bubbles particularly when the fluidized bed is under severe conditions.
  • Another object of the present invention is to provide an apparatus for carrying out this method.
  • FIG. is a side view partially in section of an embodiment of the apparatus of the present invention.
  • FIGS. 2, 3 and 4 are side views partially in section of another embodiment of the apparatus of the present invention.
  • FIGS. 5, 6, 7 and 8 are plan views showing methods for securing the transmitting and receiving wave guide rods and FIG. 9 diagrammatically illustrates the apparatus of FIG. 1 having a plurality of detection elements.
  • FIG. 1 shows a conventional reactor provided with a detector constructed in accordance with the present invention.
  • a raw material supply pipe 4 is provided at a lower portion of the tank 1 to fluidize the small particles (catalyzer) in the tank by feeding therethrough raw material (in gas phase and liquid phase) pressurized to a predetermined level by a circulating pump 3.
  • the reaction products are removed from the system through an outlet pipe 6 and separated into gas and liquid by a gas-liquid separator 16.
  • a portion of the liquid is fed back to the tank 1 by a pipe 2 and the circulating pump 3.
  • the tank 1 has a supporting body 5 at the upper portion thereof which supports a transmitting wave guide rod 9 and a receiving wave guide rod 10 passing therethrough at a fixed distance from one another.
  • Each wave guide rod extends into the interior of the tank 1 by a predeterminated length.
  • the wave guide rod 9 has extending therefrom a transmitting reflector plate 11 inclined by 45 while the wave guide rod 10 has extending therefrom a receiving reflector plate 12 inclined by 45.
  • the plates 11 and 12 are disposed so that the inclined faces thereof are in opposing relation.
  • the opposite ends of the wave guide rods 9 and 10 which are outside of the tank are connected respectively to an ultra-sonic transmitter 7 and an ultrasonic receiver 8.
  • the ultra-sonic wave transmitted from the ultra-sonic transmitter 7 is guided by the transmit ting wave guide rod 9 to the transmitting reflector plate 11, deflected thereby, transmitted through the tank to the receiving reflector plate 12, deflected 90 thereby, guided out of the reactor by the receiving wave guide rod 10 and detected, by the ultra-sonic receiver 8. Accordingly, when there are bubbles or small particles in the space 17 between the receiving reflector plate 11 and the transmitting reflector plate 12, the ultra-sonic wave is scattered in the space or absorbed by the small particles or the bubbles, so that the strength thereof is considerably reduced.
  • a plate 13 for preventing the bubbles from entering into the space 17 is provided at the lower portion of the space 17.
  • the plate 13 may be of any material which is not damaged by the liquid reactant and the shape thereof may be of any shape which does not disturb the formation of the fluidized bed.
  • the plate for preventing the bubbles from entering the space prevents the bubbles from entering the space 17 from the bottom thus ensuring that no bubbles are present between the transmitting reflector plate and the receiving reflector plate.
  • a cooling device 15 may be provided to protect the ultrasonic transmitter 7 and the ultra-sonic receiver 8 from damage due to high temperature where the reaction is performed at a high temperature.
  • FIG. 2 shows another embodiment wherein the transmitting wave guide rod 9 and its ultra-sonic transmitting reflector plate 11 are formed as one body as are the receiving wave guide rod 10 and its integrated ultra-sonic receiving reflector 12.
  • the ends of the wave guide rods 9 and 10 in the tank are cut to form end faces inclined by 45.
  • the inclined end faces are in back-to-back relation.
  • the ultra-sonic wave transmitted from the ultra-sonic transmitter is deflected by 90 at the tip of the wave guide rod 9, guided through the reactant to the inclined portion of the wave guide rod 10 deflected by 90 thereby and detected by the ultrasonic receiver through the wave guide rod 10.
  • the loss is slightly larger than that of the embodiment shown in FIG. 1 because the ultra-sonic wave transmitted is not fully reflected at the reflecting plate, the construction itself becomes simpler than that of the arrangement in FIG. 1.
  • FIG. 3 may be used in which the ultra-sonic transmitter 7 and the ultra-sonic receiver 8 are disposed in the tank 1 at a fixed interval.
  • the ultra-sonic wave is transmitted directly from the transmitter to the receiver, the detected output is converted into an electric output and the electric signal is transmitted through a lead wire to the exterior of the tank 1.
  • FIG. 4 shows another embodiment which is a combination of the embodiment shown in FIG. 1 and FIG. 3.
  • the ultra-sonic transmitter 7 is provided in the tank 1, the ultra-sonic wave is deflected by 90 by the receiving reflector plate 12 and detected through the receiving wave guide rod 10 by the ultrasonic receiver 8.
  • the transmitting output power can be minimized.
  • this method cannot be used where the reaction temperature is higher than the transition temperature of the crystal used in the ultra-sonic transmitter, i.e., 570C.
  • the transmitting wave guide rod 9 and the receiving wave guide rod 10 are held fast by supporting member through which they pass, they may, if several meters in length, be caused to vibrate by the motion of the liquid and particles. This will make it difficult to measure the ultra-sonic wave as therods may come into contact, be damaged or give rise to noise. For this reason, the vibration of the transmitting wave guide rod and the receiving wave guide rod is prevented by connecting them to each other by a supporting means 14. In this case, however, if the supporting means 14 is in the form of a single rod, as shown in FIG.
  • the ultra-sonic wave will be transmitted from the transmitting wave guide rod 9 through the supporting rod 14 to the receiving wave guide rod and thus this construction may constitute a source of noise.
  • the supporting rod 14 is provided in the vicinity of the top of the wave guide rods, it becomes difficult to distinguish the ultra-sonic wave passing through the reactant from that passing through the supporting rod because these waves are received at substantially the same time.
  • the supporting rod is secured to the wave guides 9 and 10 in a suitable manner using at least two supporting members, as shown in FIGS. 6, 7 and 8.
  • the supporting means be constituted with two separate members 14 connected with each other by welding, screws etc., in such a manner that the wave guide 9 is secured to the other memher as shown in FIGS. 6 and 7.
  • the above problem may be avoided by an unwelded connection.
  • the wave guides 9 and 10 are pinched and held by two supporting pieces 14 at the respective ends thereof, the pieces being assembled in such a way that they oppose each other as shown in FIG. 8.
  • the wave guide rods used in the present invention may be of any material which can withstand the liquid reactant and generally stainless steel is used as the wave guide material.
  • the ultra-sonic wave passes through the stainless steel to the liquid and through the liquid to the stainless steel, the wave is reflected at the interface between the stainless steel and the liquid and between the liquid and the stainless steel, and thus about percent of the strength thereof is lost.
  • the ultra-sonic wave is further attenuated to 1/1000 of its original value. Since the relation between the length of the stainless steel and the amount of attenuation is fixed, any large attenuation of the ultra-sonic wave beyond the calculated amount of attenuation indicates the existence of small particles.
  • the diameter and the length of the transmitting wave guide rod of stainless steel are 20 millimeters and 7 meters, respectively, and an ultrasonic wave of 15 volts and 1 MHz is applied thereto in the absence of small particles, about 85 percent of the energy of the wave is lost during its travel to the receiving rod, so that the receiver detects about 0.05 volts ultra-sonic wave.
  • the wave is attenuated to about 1/ 1000 of its original value and thus the strength of the received wave becomes about 0.000054 volts.
  • the degree of the attenuation of the ultra-sonic wave varies depending upon the density of the small particles and the reaction conditions etc.
  • the ultrasonic wave is greatly attenuated when the small particles exist, and therefore the detection is very easy. Furthermore, since the present invention provides separate transmitting and receiving devices, it is possible to distinguish the wave passing through the liquid from that reflected at the end faces of the wave guide rods thus making it possible to simplify the construction of the ultra-sonic receiver.
  • a tank capable of safe continuous operation can be constructed (FIG. 9) by providing a plurality of the detection apparatuses 18 of the present invention in vertical arrangement and at appropriate intervals within the tank, constantly checking the level of the small particles in the tank and controlling (or stopping) the supply of liquid and the rate of circulation by means of an automatic control device 3 when the small particles reach the predetermined level.
  • the present invention provides a means for detecting the level of small particles in a fluidized bed containing bubbles and thus easily overcomes a problem unsolved by the conventional devices.
  • the present invention makes possible the detection of the levei of the small particles where the reaction is being carried out under very severe conditions so that the reaction can proceed effectively and safely.
  • a method for detecting small particles in a tank comprising the steps of providing in said tank an ultrasonic transmitting means and an ultra-sonic receiving means opposite to each other at a fixed interval, maintaining the space between said transmitting means and said receiving means free of bubbles, transmitting an ultra-sonic wave from said transmitting means to said receiving means, and detecting the presence or absence of small particles in said space by the attenuation or lack of attenuation of said ultra-sonic wave.
  • An apparatus for detecting small particles in a tank comprising a tank, an ultra-sonic transmitting means provided in said tank, an ultra-sonic receiving means also provided in said tank oppositely to said ultra-sonic transmitting means at a fixed distance therefrom, and a plate for preventing bubbles from entering the space between said transmitting means and said receiving means whereby the presence or absence of said particles between said transmitting means and said receiving means is detected by the attenuation or lack of attenuation of an ultra-sonic wave transmitted from said transmitting means to said receiving means.
  • said receiving means is an ultra-sonic receiver connected to a lead wire leading out of said tank.

Abstract

An ultra-sonic transmitting means and an ultra-sonic receiving means are provided in fluidized region of a tank at a fixed interval. An ultra-sonic wave is transmitted from the transmitting means to the receiving means and bubbles are prevented from entering the space between the transmitting means and the receiving means, and the presence or absence of small particles is detected by measuring the attenuation of the ultrasonic wave.

Description

United States Patent 1191 Yokoyama et al. [4 1 June 5, 1973 [54] METHOD FOR DETECTING SMALL [56] References Cited PARTICLES IN A TANK AND AN UNITED STATES PATENTS APPARATUS FOR CARRYING OUT THE SAME 3,133,445 5/1964 Richard ..73/67.5 R 1 Yokoyam, sagamihara; 3223232 i233? 5233? .11: Z3511? Kan, Ykhama; 08m", 3,622,958 11/1971 Tucker ..340/1 R Kawasaki; Yoshiro llori; Kimihiko Yazawa, both of Tokyo, of Japan Primary Examiner-Benjamin A. Borchelt [73] Assignee: Chiyoda Kako Kensetsu Kabushikl Assistant Psiws Kaisha, Yokohama, Japan Kelma" [22] Filed: Oct. 26, 1971 57 ABSTRACT PP N04 192,157 An ultra-sonic transmitting means and an ultra-sonic receiving means are provided in fluidized region of a [30] Foreign Application priority m tank at a fixed interval. An ultra-sonic wave is transmitted from the transmitting means to the receiving Oct. 27,1970 Japan ..45/93937 means and bubbhas are prevented from entering the space between the transmitting means and the receiv- [52] US. Cl. ..340/15, 73/61, 73167.5, ing means, and the presence or absence of Small parti 73/67'6 cles is detected by measuring the attenuation of the 1 Int. Cl u]tra-sonic wave [58] Field of Search ..340/l R, 15; 73/61,
10 Claims, 9 Drawing Figures Patented June 5, 1973 3 Sheets-Sheet 1 Patented June 5, 1973 3 Sheets-Sheet 2 3 Sheets-Shut 5 Fig.5
Fig.6
METHOD FOR DETECTING SMALL PARTICLES IN A TANK AND AN APPARATUS FOR CARRYING OUT THE SAME The present invention relates to a method for detecting. small particles and a device for carrying out the same.
In general, the small particles contained in the liquid in a reactor sink under the pull of gravity and accumulate at the bottom of the reactor as a fixed bed. This fixed bed is converted to a fluidized bed by supplying a fluid at a predetermined rate of flow from the lower portion of the reactor. As there is good material mobility and heat transfer in the fluidized bed, this type of bed is used widely in carrying out chemical reaction, heating, cooling, drying etc..
I-Ieretofore known methods for measuring the small particles in a reactor employing the fluidized bed include those utilizing the difference in density of the materials in the reactor and those utilizing the change in electrostatic capacitance. In the conventional methods, although it is possible to obtain relatively correct measurement when bubbles do not exist in the reactor, it is impossible to measure the small particles accurately when the fluid to be supplied to the reactor includes both gas and liquid phase materials because the gas phase materials, i.e., the bubbles are detected indistinguishably from the small particles. A method is also known in which an ultrasonic transmitting apparatus and an ultra-sonic receiving apparatus are provided in the tank and the small particles are detected by measuring the time duration between transmission and reception of the ultra-sonic wave. In this method, however, it is very difficult to distinguish the ultra-sonic waves reflected by the small particles from those reflected by the bubbles because, where the small particles coexist with the bubbles, the ultra-sonic wave is also reflected by the bubbles. In particular, where the reaction must be performed under severe conditions, such as in the case of the hydrogenolysis of the reduced pressure residual oil which is performed at 200 atms and at 450C, the existence of the small particles in the tank is detected by utilizing gamma rays. In this method the tank is irradiated by gamma rays from the inside and the gamma rays penetrating the tank are measured by a counter. The thickness of the tank in the vicinity of the area where the measuring is performed is made thinner in order to minimize the absorption of the gamma rays by the tank.TAs a result, the ability of the tank to withstand high pressure is reduced thus increasing the danger of explosion of the tank.
One object of the present invention is to provide a method for easily detecting the existence of small particles in a fluidized bed containing bubbles particularly when the fluidized bed is under severe conditions.
Another object of the present invention is to provide an apparatus for carrying out this method.
Other objects and features of the present invention will become apparent from the following description with reference to the attached drawings, in which:
FIG. is a side view partially in section of an embodiment of the apparatus of the present invention;
FIGS. 2, 3 and 4 are side views partially in section of another embodiment of the apparatus of the present invention;
FIGS. 5, 6, 7 and 8 are plan views showing methods for securing the transmitting and receiving wave guide rods and FIG. 9 diagrammatically illustrates the apparatus of FIG. 1 having a plurality of detection elements.
FIG. 1 shows a conventional reactor provided with a detector constructed in accordance with the present invention. A raw material supply pipe 4 is provided at a lower portion of the tank 1 to fluidize the small particles (catalyzer) in the tank by feeding therethrough raw material (in gas phase and liquid phase) pressurized to a predetermined level by a circulating pump 3. The reaction products are removed from the system through an outlet pipe 6 and separated into gas and liquid by a gas-liquid separator 16. A portion of the liquid is fed back to the tank 1 by a pipe 2 and the circulating pump 3. The tank 1 has a supporting body 5 at the upper portion thereof which supports a transmitting wave guide rod 9 and a receiving wave guide rod 10 passing therethrough at a fixed distance from one another. Each wave guide rod extends into the interior of the tank 1 by a predeterminated length. The wave guide rod 9 has extending therefrom a transmitting reflector plate 11 inclined by 45 while the wave guide rod 10 has extending therefrom a receiving reflector plate 12 inclined by 45. The plates 11 and 12 are disposed so that the inclined faces thereof are in opposing relation. The opposite ends of the wave guide rods 9 and 10 which are outside of the tank are connected respectively to an ultra-sonic transmitter 7 and an ultrasonic receiver 8. The ultra-sonic wave transmitted from the ultra-sonic transmitter 7 is guided by the transmit ting wave guide rod 9 to the transmitting reflector plate 11, deflected thereby, transmitted through the tank to the receiving reflector plate 12, deflected 90 thereby, guided out of the reactor by the receiving wave guide rod 10 and detected, by the ultra-sonic receiver 8. Accordingly, when there are bubbles or small particles in the space 17 between the receiving reflector plate 11 and the transmitting reflector plate 12, the ultra-sonic wave is scattered in the space or absorbed by the small particles or the bubbles, so that the strength thereof is considerably reduced.
In the present invention, in order to avoid the attenuation of the ultrasonic wave by the bubbles, a plate 13 for preventing the bubbles from entering into the space 17 is provided at the lower portion of the space 17. The plate 13 may be of any material which is not damaged by the liquid reactant and the shape thereof may be of any shape which does not disturb the formation of the fluidized bed.
The plate for preventing the bubbles from entering the space prevents the bubbles from entering the space 17 from the bottom thus ensuring that no bubbles are present between the transmitting reflector plate and the receiving reflector plate. Thus, if the ultra-sonic wave received by the ultra-sonic receiver 8 is considerably attenuated, the existence of the small particles is affirmed and if there is no attenuation of the ultra-sonic wave, the small particles have not reached the predetermined level yet.
A cooling device 15 may be provided to protect the ultrasonic transmitter 7 and the ultra-sonic receiver 8 from damage due to high temperature where the reaction is performed at a high temperature.
FIG. 2 shows another embodiment wherein the transmitting wave guide rod 9 and its ultra-sonic transmitting reflector plate 11 are formed as one body as are the receiving wave guide rod 10 and its integrated ultra-sonic receiving reflector 12. The ends of the wave guide rods 9 and 10 in the tank are cut to form end faces inclined by 45. The inclined end faces are in back-to-back relation. The ultra-sonic wave transmitted from the ultra-sonic transmitter is deflected by 90 at the tip of the wave guide rod 9, guided through the reactant to the inclined portion of the wave guide rod 10 deflected by 90 thereby and detected by the ultrasonic receiver through the wave guide rod 10. In this embodiment, although the loss is slightly larger than that of the embodiment shown in FIG. 1 because the ultra-sonic wave transmitted is not fully reflected at the reflecting plate, the construction itself becomes simpler than that of the arrangement in FIG. 1.
Where the reaction temperature of the tank is relatively low, an arrangement as shown in FIG. 3 may be used in which the ultra-sonic transmitter 7 and the ultra-sonic receiver 8 are disposed in the tank 1 at a fixed interval. In this arrangement, the ultra-sonic wave is transmitted directly from the transmitter to the receiver, the detected output is converted into an electric output and the electric signal is transmitted through a lead wire to the exterior of the tank 1.
FIG. 4 shows another embodiment which is a combination of the embodiment shown in FIG. 1 and FIG. 3. In this embodiment, the ultra-sonic transmitter 7 is provided in the tank 1, the ultra-sonic wave is deflected by 90 by the receiving reflector plate 12 and detected through the receiving wave guide rod 10 by the ultrasonic receiver 8.
By providing the ultra-sonic transmitter in the tank as in the embodiments shown in FIGS. 3 and 4, the transmitting output power can be minimized. However, this method cannot be used where the reaction temperature is higher than the transition temperature of the crystal used in the ultra-sonic transmitter, i.e., 570C.
Although the transmitting wave guide rod 9 and the receiving wave guide rod 10 are held fast by supporting member through which they pass, they may, if several meters in length, be caused to vibrate by the motion of the liquid and particles. This will make it difficult to measure the ultra-sonic wave as therods may come into contact, be damaged or give rise to noise. For this reason, the vibration of the transmitting wave guide rod and the receiving wave guide rod is prevented by connecting them to each other by a supporting means 14. In this case, however, if the supporting means 14 is in the form of a single rod, as shown in FIG. 5 and the wave guide rods are secured to the respective ends of the supporting rod by welding etc., the ultra-sonic wave will be transmitted from the transmitting wave guide rod 9 through the supporting rod 14 to the receiving wave guide rod and thus this construction may constitute a source of noise. In particular, when the supporting rod 14 is provided in the vicinity of the top of the wave guide rods, it becomes difficult to distinguish the ultra-sonic wave passing through the reactant from that passing through the supporting rod because these waves are received at substantially the same time. In order to avoid this problem, the supporting rod is secured to the wave guides 9 and 10 in a suitable manner using at least two supporting members, as shown in FIGS. 6, 7 and 8. When the connection of the wave guides 9 and 1.0 to the supporting means is made by welding, it is preferable that the supporting means be constituted with two separate members 14 connected with each other by welding, screws etc., in such a manner that the wave guide 9 is secured to the other memher as shown in FIGS. 6 and 7. Alternatively, the above problem may be avoided by an unwelded connection. In this case, the wave guides 9 and 10 are pinched and held by two supporting pieces 14 at the respective ends thereof, the pieces being assembled in such a way that they oppose each other as shown in FIG. 8.
The wave guide rods used in the present invention may be of any material which can withstand the liquid reactant and generally stainless steel is used as the wave guide material. When the ultra-sonic wave passes through the stainless steel to the liquid and through the liquid to the stainless steel, the wave is reflected at the interface between the stainless steel and the liquid and between the liquid and the stainless steel, and thus about percent of the strength thereof is lost. Furthermore, when the small particles exist, the ultra-sonic wave is further attenuated to 1/1000 of its original value. Since the relation between the length of the stainless steel and the amount of attenuation is fixed, any large attenuation of the ultra-sonic wave beyond the calculated amount of attenuation indicates the existence of small particles.
As an example, when the diameter and the length of the transmitting wave guide rod of stainless steel are 20 millimeters and 7 meters, respectively, and an ultrasonic wave of 15 volts and 1 MHz is applied thereto in the absence of small particles, about 85 percent of the energy of the wave is lost during its travel to the receiving rod, so that the receiver detects about 0.05 volts ultra-sonic wave. On the other hand, when small particles exist between the rods the wave is attenuated to about 1/ 1000 of its original value and thus the strength of the received wave becomes about 0.000054 volts. Of course the degree of the attenuation of the ultra-sonic wave varies depending upon the density of the small particles and the reaction conditions etc. However, as above mentioned, the ultrasonic wave is greatly attenuated when the small particles exist, and therefore the detection is very easy. Furthermore, since the present invention provides separate transmitting and receiving devices, it is possible to distinguish the wave passing through the liquid from that reflected at the end faces of the wave guide rods thus making it possible to simplify the construction of the ultra-sonic receiver.
A tank capable of safe continuous operation can be constructed (FIG. 9) by providing a plurality of the detection apparatuses 18 of the present invention in vertical arrangement and at appropriate intervals within the tank, constantly checking the level of the small particles in the tank and controlling (or stopping) the supply of liquid and the rate of circulation by means of an automatic control device 3 when the small particles reach the predetermined level.
While the drawings show embodiments using a trans mitting wave guide rod and a receiving wave guide rod disposed in parallel, it should be noted that many modifications of the rod arrangement can be made within the scope of the present invention, and as an example, these rods may be arranged in such a manner that they are disposed oppositely or one of them makes an angle to the other.
In summary the present invention provides a means for detecting the level of small particles in a fluidized bed containing bubbles and thus easily overcomes a problem unsolved by the conventional devices. In particular the present invention makes possible the detection of the levei of the small particles where the reaction is being carried out under very severe conditions so that the reaction can proceed effectively and safely.
What is claimed is:
1. A method for detecting small particles in a tank comprising the steps of providing in said tank an ultrasonic transmitting means and an ultra-sonic receiving means opposite to each other at a fixed interval, maintaining the space between said transmitting means and said receiving means free of bubbles, transmitting an ultra-sonic wave from said transmitting means to said receiving means, and detecting the presence or absence of small particles in said space by the attenuation or lack of attenuation of said ultra-sonic wave.
2. An apparatus for detecting small particles in a tank, comprising a tank, an ultra-sonic transmitting means provided in said tank, an ultra-sonic receiving means also provided in said tank oppositely to said ultra-sonic transmitting means at a fixed distance therefrom, and a plate for preventing bubbles from entering the space between said transmitting means and said receiving means whereby the presence or absence of said particles between said transmitting means and said receiving means is detected by the attenuation or lack of attenuation of an ultra-sonic wave transmitted from said transmitting means to said receiving means.
3. The apparatus defined in claim 2, wherein saidv transmitting means and said receiving means are in the form of rods connected at one end respectively to an ultra-sonic transmitter means and an ultra-sonic receiving means located outside of said tank.
4. The apparatus defined in claim 3, wherein said plate for preventing the bubbles from entering said space is provided on an extension of a transmitting rod.
5. The apparatus defined in claim 3, wherein the other end of said transmitting rod and the other end of said receiving rod have inclined faces in opposing rela tion.
6. The apparatus defined in claim 3, wherein a member having an inclined face is disposed on said extension of said transmitting rod and on an extension of said receiving rod.
7. The apparatus defined in claim 2, wherein said transmitting means is an ultra-sonic transmitter connected to a lead wire leading out of said tank.
8. The apparatus defined in claim 2, wherein said receiving means is an ultra-sonic receiver connected to a lead wire leading out of said tank.
9. The apparatus defined in claim 3, wherein said rods are supported in parallel relation by at least two members which are welded to said rods and connected with each other in such a manner that the connection between said members absorbs the stress of said rods.
10. The apparatus of claim 2 wherein a plurality of ultrasonic transmitting means and ultra-sonic receiving means are disposed in said tank at different levels.

Claims (10)

1. A method for detecting small particles in a tank comprising the steps of providing in said tank an ultra-sonic transmitting means and an ultra-sonic receiving means opposite to each other at a fixed interval, maintaining the space between said transmitting means and said receiving means free of bubbles, transmitting an ultra-sonic wave from said transmitting means to said receiving means, and detecting the presence or absence of small particles in said space by the attenuation or lack of attenuation of said ultra-sonic wave.
2. An apparatus for detecting small particles in a tank, comprising a tank, an ultra-sonic transmitting means provided in said tank, an ultra-sonic receiving means also provided in said tank oppositely to said ultra-sonic transmitting means at a fixed distance therefrom, and a plate for preventing bubbles from entering the space between said transmitting means and said receiving means whereby the presence or absence of said particles between said transmitting means and said receiving means is detected by the attenuation or lack of attenuation of an ultra-sonic wave transmitted from said transmitting means to said receiving means.
3. The apparatus defined in claim 2, wherein said transmitting means and said receiving means are in the form of rods connected at one end respectively to an ultra-sonic transmitter means and an ultra-sonic receiving means located outside of said tank.
4. The apparatus defined in claim 3, wherein said plate for preventing the bubbles from entering said space is provided on an extension of a transmitting rod.
5. The apparatus defined in claim 3, wherein the other end of said transmitting rod and the other end of said receiving rod have inclined faces in opposing relation.
6. The apparatus defined in claim 3, wherein a member having an inclined face is disposed on said extension of said transmitting rod and on an extension of said receiving rod.
7. The apparatus defined in claim 2, wherein said transmitting means is an ultra-sonic transmitter connected to a lead wire leading out of said tank.
8. The apparatus defined in claim 2, wherein said receiving means is an ultra-sonic receiver connected to a lead wire leading out of said tank.
9. The apparatus defined in claim 3, wherein said rods are supported in parallel relation by at least two members which are welded to said rods and connected with each other in such a manner that the connection between said members absorbs the stress of said rods.
10. The apparatus of claim 2 wherein a plurality of ultrasonic transmitting means and ultra-sonic receiving means are disposed in said tank at different levels.
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Cited By (8)

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US3921622A (en) * 1973-02-27 1975-11-25 Edward Michael Cole Method and apparatus for ultrasonic detection of inclusions in a flowing fluid
US4327587A (en) * 1978-08-01 1982-05-04 Vyzkumny ustav chemickych zrizeni Method of and apparatus for the continuous measurement of changes in rheological properties of monomers during polymerization
US4415408A (en) * 1981-11-02 1983-11-15 General Signal Corporation Apparatus, and method for controlling consistency
US4672851A (en) * 1986-05-30 1987-06-16 The United States Of America As Represented By The Secretary Of Commerce Acoustic evaluation of thermal insulation
US4825688A (en) * 1987-07-02 1989-05-02 Kraus Jr Robert P Apparatus for sensing of mass in baths
US5236473A (en) * 1992-11-10 1993-08-17 Eastman Kodak Company Sipper tube with ultrasonic debubbling
WO1999004234A1 (en) * 1997-07-16 1999-01-28 Canadian Space Agency Pressure sensor
WO1999060349A1 (en) * 1998-05-20 1999-11-25 Drexelbrook Controls, Inc. Transducer surface clearing method and apparatus

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US3921622A (en) * 1973-02-27 1975-11-25 Edward Michael Cole Method and apparatus for ultrasonic detection of inclusions in a flowing fluid
US4327587A (en) * 1978-08-01 1982-05-04 Vyzkumny ustav chemickych zrizeni Method of and apparatus for the continuous measurement of changes in rheological properties of monomers during polymerization
US4415408A (en) * 1981-11-02 1983-11-15 General Signal Corporation Apparatus, and method for controlling consistency
US4672851A (en) * 1986-05-30 1987-06-16 The United States Of America As Represented By The Secretary Of Commerce Acoustic evaluation of thermal insulation
US4825688A (en) * 1987-07-02 1989-05-02 Kraus Jr Robert P Apparatus for sensing of mass in baths
US5236473A (en) * 1992-11-10 1993-08-17 Eastman Kodak Company Sipper tube with ultrasonic debubbling
WO1999004234A1 (en) * 1997-07-16 1999-01-28 Canadian Space Agency Pressure sensor
WO1999060349A1 (en) * 1998-05-20 1999-11-25 Drexelbrook Controls, Inc. Transducer surface clearing method and apparatus

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