GB2452311A

GB2452311A - A temperature monitoring device and a method of monitoring temperature using such a device

Info

Publication number: GB2452311A
Application number: GB0716946A
Authority: GB
Inventors: Stephen James Boyce; Brian Morrie Back
Original assignee: Radio Tech Ltd
Current assignee: Radio Tech Ltd
Priority date: 2007-08-31
Filing date: 2007-08-31
Publication date: 2009-03-04
Also published as: GB0716946D0

Abstract

A temperature monitoring device 1 and corresponding method in which the temperature monitoring device 1 comprises at least one first flow control valve 9, 11 operable between open and closed states to periodically permit the flow of a fluid between at least one first inlet 10, 12 and an outlet 6. A temperature sensor 5 is arranged to measure the temperature of the fluid in the flow path between the at least one first inlet 9, 11 and outlet 6 and generates temperature data. A communication unit 7 is connected to the temperature sensor 5 for communicating the generated temperature data to a receiver unit (not illustrated). The at least one first control valve 9, 11 is operable between open and closed states to periodically permit the flow of fluid between the at least one first fluid inlet and the outlet 6. The temperature sensor 5, the communication unit 7 and the at least one first flow control valve 9, 11 are controllable by a microprocessor 4.

Description

I

Temperature Monitoring Device and Method The present invention relates, in general, to a temperature monitoring device and method for automatically measuring and communicating the temperature of a fluid to a receiver unit.

Temperature monitoring devices are well known and are used in a variety of applications where it is important to receive temperature data measurements.

Such applications may include legionella monitoring, food safety, paint storage, chemical manufacture and storage, pharmaceutical manufacture and storage, road and rail transport and the storage of artefacts.

For example, patent publication KR 2003-0044538 discloses a system for the remote management of a facility such as a fish farm or nuclear power plant.

According to KR 2003-0044538 a sensing unit or temperature probe is disposed in the water of the fish farm or in a nuclear reactor in order to measure and transmit temperature data. S. * * * S..

*. In patent publication GB 2434207 a domestic plumbing system is disclosed in S...

which a water and energy cost monitor comprises temperature sensors and flow rate monitors disposed between a shower head and water source. When the shower head is in use and water is permitted to flow, data is provided to a 2. remote unit about the water temperature and flow rate. This way, a user can determine energy and water consumption and subsequently adjust temperature and flow rate so that the system is operating at maximum efficiency.

According to GB 2434207 unless a user is present to operate the shower head no flow of water occurs and if used the temperature sensor monitors the temperature of stagnant water.

According to a first aspect of the present invention, there is provided a temperature monitoring device comprising: a first inlet for receiving a fluid and an outlet for discharging the fluid from the device; a temperature sensor arranged to measure the temperature of the fluid in a flow path between the first inlet and outlet and generate temperature data; a communication unit connected to the temperature sensor for communicating the generated temperature data to a receiver unit; wherein the temperature monitoring device further comprises a first flow control valve operable between open and closed states to periodically permit the flow of the fluid between the first inlet and outlet and the temperature sensor, the communication unit and the first flow control valve are controllable by a microprocessor.

The present invention therefore provides a valve to control the periodic flow of fluid through the temperature monitoring device. The periodic flow of fluid is S...

**** advantageous where regulations stipulate that temperature monitoring should :::: be carried out at specified time intervals and/or at fluid flow conditions representative of when a user would use the device. e ** * . .

* 2 For example, strict guidelines and controls exist for the monitoring of systems where legionella can exist. Legionella is a gram negative bacterium including species that cause legionellosis or Legionnaires disease. Common sources of Legionella include cooling towers used in industrial cooling water systems, air conditioning systems and domestic hot water systems. Temperature is known to affect the survival of Legionellae and so regulations specify that potential sources of Legionellae are maintained at either a temperature above that which Legionellae can exist or below a temperature at which they become dormant.

Typically, in order to monitor the temperature of water, a trained operative must visit a site to operate the various taps to provide a water flow and temperature representative of normal usage. Such an approach can be subject to human error and costly to implement. Since the present invention permits an automated device and method of monitoring the temperature of a fluid, the present invention obviates or at least mitigates the sources of human error and excess costs.

Preferably, the temperature sensor is connected between the first flow control valve and the outlet. Preferably, a second inlet is connected to a second flow control valve operable between open and closed states to periodically permit the flow of the fluid between the second inlet and outlet, wherein the temperature sensor is connected between the second control valve and the S...

outlet.

Preferably, when in use, the second inlet receives a fluid at a different temperature to the first inlet.

2:' The device can therefore comprise either one inlet connectable to, for example, a single water supply pipe which can be water supplied at a specified usable temperature or two inlets connectable to, for example, a hot and cold water supply pipe respectively.

Preferably, the microprocessor is programmed with data operable to control the temperature sensor to generate temperature data for a predetermined portion of time that the flow control valve is in an open state.

The predetermined portion of time can be sufficient to expel the stagnant fluid from the system so that the fluid reaches a temperature and flow rate indicative of real user requirements.

Preferably, the microprocessor is programmed with data operable to control the first and/or second flow control valve to periodically permit the flow of the fluid between the first and/or second inlet and outlet for a predetermined period of time.

The first and/or second control valves can be operable to conform to guidelines specified to cover the frequency of temperature testing and the flow rate of fluid required in testing.

If required the predetermined period of time can be made dependent upon the temperature of the fluid. * S S...

Preferably, the microprocessor is located within the device and is S...

: programmable remotely. Preferably, the device comprises an internal power source which can be a battery unit.

Preferably, the communication unit is configured to communicate the temperature data to the receiver unit as a wireless communication.

Alternatively, the communication unit can be hard wired to the receiver unit.

Where wireless communication is employed, the wireless communication is selected from SMS, GSM, GPRS, SRD (Short Range Devices), Low Power Radio, Infra-Red or Bluetooth communication.

Preferably, the communication unit communicates an alarm signal if the temperature data corresponds to a predetermined value or range. The alarm can automatically trigger a safety protocol system to be followed.

Preferably, the fluid is a liquid or a gas. Where the fluid is a liquid, the fluid is preferably water.

The present invention can be applied to, for example, domestic or industrial heating and water systems. According to a second aspect of the present invention, there is therefore provided a plumbing assembly including a temperature monitoring device as discussed herein, wherein the first inlet is connected to a fluid source, the outlet is connected to a waste outlet and the first flow control valve is operable to permit the flow of the fluid out of the waste outlet.

By connecting the outlet direct to a waste outlet, the outlet path by-passes a tap .... outlet visible to a user and so temperature monitoring can be carried out hidden r. from users. e. *

According to a third aspect of the present invention, there is provided a plumbing assembly including a temperature monitoring device as discussed

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herein, wherein the first inlet is connected to a fluid source, the outlet is connected to a tap outlet and the first flow control valve is operable to permit the flow of the fluid out of the tap outlet.

By connecting the outlet to a tap outlet, the device can be plumbed in series with the tap outlet.

According to a fourth aspect of the present invention, there is provided a method of automating the monitoring of the temperature of a fluid comprising: periodically opening a first flow control valve to permit the fluid to flow along a flow path between a first inlet and outlet; measuring the temperature of the fluid along the flow path; generating temperature data of the fluid; and transmitting the generated temperature to receiver unit, wherein at least one of the generating temperature data, transmitting temperature data and periodically opening the first flow control valve are controlled by a microprocessor.

Preferably, the method includes generating temperature data for a predetermined portion of time that the flow control valve is in an open state.

More preferably, the method includes controlling the first flow control valve to periodically permit the flow of the fluid between the first and/or second inlet and is outlet for a predetermined period of time.

*::::* It is therefore provided a temperature measuring device and method capable of :::: providing a close representation of temperature behaviour over a specified operating time. Improved data collection and accuracy is thereby obtained.

r*':* Such improved data collection can be used as an indication of early legionella activity in a water system and allow action to be taken to avoid contamination of the system before it is too late to do so. The device and method also provide real-time transmission of temperature data.

Embodiments of the present invention will now be described, by way of example only, and with reference to the accompanying drawings in which: Figure 1 is a schematic diagram of a temperature monitoring device according to a first embodiment of the present invention; Figure 2 is a schematic diagram of a temperature monitoring device installed in a plumbing system according to a second embodiment of the present invention; Figure 3 is a schematic diagram of a temperature monitoring device installed in a plumbing system according to a third embodiment of the present invention; and Figure 4 is a schematic diagram of a temperature monitoring device installed in a plumbing system according to a fourth embodiment of the present invention.

Throughout the following description, like reference numerals are used to identify like parts.

Referring to Figure 1, a temperature monitoring device I according to a first . embodiment of the present invention comprises a housing with a lid (not shown) defining an open cavity 13. A temperature sensor 5 is disposed adjacent an outlet pipe 6 in the flow path 8 between a first inlet pipe 10, second inlet pipe 12 and outlet pipe 6. The first inlet pipe 10 is connected to a first flow control solenoid valve 9 and the second inlet pipe 12 is connected to a second flow control solenoid valve 11 which control the flow of a fluid along the flow path 8 from the first inlet pipe 10 and second inlet pipe 12 to the outlet pipe 6 respectively.

Also within the device I is disposed electronic circuitry comprising a processing unit 4 and an antenna 7. The antenna 7 is capable of acting as a transmitter and communicating data under the control of the processing unit 4 to a receiver unit (not shown). The communication can be by wire or cable or wireless.

Where the communication is by wireless means the medium of communication can be SMS, GSM, GPRS, SRD (Short Range Devices), Low Power Radio, Infra-Red or Bluetooth communication. The temperature sensor 5 and the antenna 7 are connected to the processing unit 4. An internal power supply 3 such as a battery is connected to the device I and connected to the first and second flow control solenoid valves 9, 11, and the processing unit 4.

The processing unit 4 is a programmable microprocessor and can comprise a Random Access Memory (RAM), Read Only Memory (ROM) and non-volatile memory. The programmable microprocessor can be programmed prior to use to carry out a number of predetermined tasks or can be updated with programmed tasks in real time in which case the antenna 7 can act as a receiving unit.

In use and according to a second embodiment of the present invention, Figure 2 illustrates two temperature monitoring devices Ia and lb plumbed into a domestic hot and cold water supply assembly 20. The two temperature * monitoring devices Ia and lb differ from the temperature monitoring device I as described above in connection with Figure 1 in that they comprise only one inlet pipe 10 or 12 respectively. The first inlet pipe 10 is connected to a hot water supply source 22 and the second inlet pipe 12 is connected to a cold water supply source 24. The outlet pipe 6 of both the temperature monitoring devices I a and I b are connected to a waste outlet 26.

At predetermined intervals of time, for example, monthly, and for predetermined periods of time, for example four minutes duration, the first flow control solenoid valve 9 disposed within the temperature monitoring device Ia is engaged to an open position under the control of the processing unit 4 so that hot water can flow from the hot water supply source 22 to the temperature monitoring device Ia. As best seen in Figure 1, the flow path 8 of the hot water passes the temperature sensor 5 where temperature data can be generated. In case of air pressure build up an air inlet valve 2 is provided in the flow path 8. The hot water is discharged from the outlet pipe 6 via the waste outlet 26.

The generated temperature data is communicated to the processing unit 4 and Communicated by wireless means or otherwise to a receiving unit. The data can be stored, reviewed or used to raise an alarm if the data indicates that certain specified safety protocols have not been met. S.

After the temperature monitoring is complete, the first flow control solenoid valve 9 is engaged to a closed position under the control of the processing unit S...

4 50 that hot water ceases to flow from the hot water supply source 22 to the outlet pipe 6. The processing unit can cause the temperature sensor 5 to 2D generate temperature data when the first flow control solenoid valve 9 is engaged to a closed position so that a comparison can be made between the open and closed states.

The above temperature monitoring can be repeated as desired for the hot 22 and cold 24 water supplies.

Referring to Figure 3, a temperature monitoring device I in use according to a third embodiment of the present invention comprises two inlet pipes 10, 12 for receiving a hot water supply source 22 and a cold water supply source 24 respectively. In use, the first or second flow solenoid valve 9, 11 disposed within the temperature monitoring device 1 is engaged to an open position under the control of the processing unit 4 so that hot or cold water can flow from the hot water supply source 22 or the cold water supply source 24 to the temperature monitoring device 1. As best seen in Figure 1, the flow path 8 of the hot or cold water passes the temperature sensor 5 where temperature data can be generated. The hot water or cold water is subsequently discharged from the outlet pipe 6 via the waste outlet 26. The temperature data is processed as described above in connection with Figure 2.

Referring to Figure 4, a schematic diagram of a temperature monitoring device 1 installed in a plumbing system according to a fourth embodiment of the S...

present invention comprises the temperature monitoring device disposed in *:::: series with the hot and/or cold water supply sources 22, 24. Such an arrangement can be found where a tap 40 is operable by an infra-red sensor 42 r2':* by a user. The discharged water can be a mixed hot and cold water supply. S..

S

In use, the first and/or second solenoid valve 9, 11 is engaged to an open position under the control of the processing unit 4 so that hot or cold water or a mixture of both can flow from the hot water supply source 22 or the cold water supply source 24 to the temperature monitoring device 1. The outlet pipe 6 is directly connected to the tap 40 so that water is discharged through sink 44.

The temperature data is processed as described above in connection with Figure 2.

The fourth embodiment enables the assembly 20 to be flushed and removes the need to isolate the temperature monitoring device I from the assembly 20.

No doubt many other effective alternatives will occur to the skilled person. It will be understood that the invention is not limited to the described embodiments and encompasses modifications apparent to those skilled in the art lying within the spirit and scope of the claims appended hereto. S. * S * .1. * .. * *.* *5I * *. S. S S. Se * S S * S

S *SS

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Claims

Claims 1. A temperature monitoring device comprising: a first inlet for receiving a fluid and an outlet for discharging the fluid from the device; a temperature sensor arranged to measure the temperature of the fluid in a flow path between the first inlet and outlet and generate temperature data; a communication unit connected to the temperature sensor for communicating the generated temperature data to a receiver unit; wherein the temperature monitoring device further comprises a first flow control valve operable between open and closed states to periodically permit the flow of the fluid between the first inlet and outlet and the temperature sensor, the communication unit and the first flow control valve are controllable by a microprocessor.
2. A device as claimed in claim 1, wherein the temperature sensor is : ... connected between the first flow control valve and the outlet. * * S.-.
3. A device as claimed in any preceding claim, comprising a second inlet connected to a second flow control valve operable between open r *:* and closed states to periodically permit the flow of the fluid between the second inlet and outlet, wherein the temperature sensor is connected between the second control valve and the outlet.
4. A device as claimed in claim 3, wherein, when in use, the second inlet receives a fluid at a different temperature to the first inlet.
5. A device as claimed in any preceding claim, wherein the microprocessor is programmed with data operable to control the temperature sensor to generate temperature data for a predetermined portion of time that the flow control valve, is in an open state.
6. A device as claimed in any one of claims 3 to 5, wherein the microprocessor is programmed with data operable to control the first and/or second flow control valve to periodically permit the flow of the fluid between the first and/or second inlet and outlet for a predetermined period of time.
7. A device as claimed in claim 6, wherein the predetermined period of time is dependent upon the temperature of the fluid.
8. A device as claimed in any preceding claim, wherein the :..15 microprocessor is located within the device and is programmable S...

**,. remotely.
9. A device as claimed in any preceding claim, wherein the device comprises an internal power source. *. ..
10. A device as claimed in claim 9, wherein the internal power source is a battery unit.
11. A device as claimed in any preceding claim, wherein the communication unit is configured to communicate the temperature data to the receiver unit as a wireless communication.
12. A device as claimed in claim 11, wherein the wireless communication is selected from SMS, GSM, GPRS, SRD (Short Range Devices), Low Power Radio, Infra-Red or Bluetooth communication.
13. A device as claimed in any preceding claim, wherein the communication unit communicates an alarm signal if the temperature data corresponds to a predetermined value or range.
14. A device as claimed in any preceding claim, wherein the fluid is a liquid or a gas.
15. A device as claimed in claim 14, wherein the liquid is water.
16. A plumbing assembly including a temperature monitoring device as claimed in any preceding claim, wherein the first inlet is connected to a fluid source, the outlet is connected to a waste outlet and the first S...

: flow control valve is operable to permit the flow of the fluid out of the waste outlet. S. .. * S * S *

*.
17. A plumbing assembly including a temperature monitoring device as claimed in any one of claims 1 to 15, wherein the first inlet is connected to a fluid source, the outlet is connected to a tap outlet and the first flow control valve is operable to permit the flow of the fluid out of the tap outlet.
18. A method of automating the monitoring of the temperature of a fluid comprising: periodically opening a first flow control valve to permit the fluid to flow along a flow path between a first inlet and outlet; measuring the temperature of the fluid along the flow path; generating temperature data of the fluid; and transmitting the generated temperature to receiver unit, wherein at least one of the generating temperature data, transmitting temperature data and periodically opening the first flow control valve are controlled by a microprocessor.
19. A method as claimed in claim 18 including generating temperature data for a predetermined portion of time that the flow control valve is in an open state.
20. A method as claimed in claim 18 or 19 including controlling the first flow control valve to periodically permit the flow of the fluid between the first and/or second inlet and outlet for a predetermined period of time. * . *
21. A temperature monitoring device substantially as hereinbefore described and/or with reference to Figures 1 to 4 of the accompanying drawings.
22. A method of automating the monitoring of the temperature of a fluid substantially as hereinbefore described and/or with reference to Figures 1 to 4 of the accompanying drawings.