18 Royalty-Free Audio Tracks for "Time Beep"

Clock beep sound.

I made a script in python with three balls bouncing around at different speed. When the ball hits a wall a beep is played. The slowest bass plays a 110hz beep. The middle ball a 220hz beep and the fastest a 440hz beep. Python can’t play two beeps at a time…sort of random “music”… you control the rhythm with the ball speed.

The zero alert tone on the drumometerhttps://www. Drumometer. Com.

A beeping noise, with long pauses in between beeps at first, then shorter and shorter until a continuous beep. . . Could be used like a timebomb i guess.

I made a small python program that generates 20 random beeps. I record the outcome. I cut the result so that the first beep starts after 0. 01 secthe file ends right after the last beep. (i'm a python noob. . . If you find something you don’t like in the code please let me know. ). # gis_sweden 20170531 - random beep in python :-)import winsoundimport randomimport timebeepnr = 1. While beepnr < 21:freq = random. Randrange(1000)+110dur1 = random. Randrange(700)+20dur2 = random. Randrange(10)+2winsound. Beep (freq, dur1)time. Sleep(dur2/10)print 'beep number', beepnrbeepnr = beepnr + 1.

I made a small python program that generates 20 random beeps. I record the outcome. I cut the result so that the first beep starts after 0. 01 secthe file ends right after the last beep. (i'm a python noob. . . If you find something you don’t like in the code please let me know. ). # gis_sweden 20170531 - random beep in python :-)import winsoundimport randomimport timebeepnr = 1. While beepnr < 21:freq = random. Randrange(1000)+110dur1 = random. Randrange(700)+20dur2 = random. Randrange(10)+2winsound. Beep (freq, dur1)time. Sleep(dur2/10)print 'beep number', beepnrbeepnr = beepnr + 1.

I made a small python program that generates 20 random beeps. I record the outcome. I cut the result so that the first beep starts after 0. 01 secthe file ends right after the last beep. (i'm a python noob. . . If you find something you don’t like in the code please let me know. ). # gis_sweden 20170531 - random beep in python :-)import winsoundimport randomimport timebeepnr = 1. While beepnr < 21:freq = random. Randrange(1000)+110dur1 = random. Randrange(700)+20dur2 = random. Randrange(10)+2winsound. Beep (freq, dur1)time. Sleep(dur2/10)print 'beep number', beepnrbeepnr = beepnr + 1.

Stereoi captured it during my time at a hotel. Zoom h4n built in microphone.

I made a small python program that generates 20 random beeps. I record the outcome. I cut the result so that the first beep starts after 0. 01 secthe file ends right after the last beep. (i'm a python noob. . . If you find something you don’t like in the code please let me know. ). In this sound i have joined three "beep files". Sound 1 panned to the leftsound 2 in the centersound 3 panned to the right. # gis_sweden 20170531 - random beep in python :-)import winsoundimport randomimport timebeepnr = 1. While beepnr < 21:freq = random. Randrange(1000)+110dur1 = random. Randrange(700)+20dur2 = random. Randrange(10)+2winsound. Beep (freq, dur1)time. Sleep(dur2/10)print 'beep number', beepnrbeepnr = beepnr + 1.

This is a precise emulation of the audible time signal broadcast by radio station wwv of the nist in the usa on shortwave. This recording was produced via a program i wrote that emulates the time signal and recreates it from scratch, but it conforms precisely to the specs of the real signal. The only part missing is the voice announcement of the time, which, in the real broadcast, is made during the last fifteen seconds of each minute (which is why the tone changes to just clicks during that time). There are two minutes in the recording, but it should be easy to loop it or otherwise modify it for other durations. Since this audio file was computer-generated from scratch, it contains no noise, but the real broadcast has some static and noise, especially at large distances from the transmitter in colorado. Generated by special software / 48. 1 khz 16-bit stereo.

A recording made around noon on the edge of a woods located right in the middle of a major midwestern university. Throughout this entire recording, you'll hear the everpresent hum of heating and air conditioner units running. You will also hear faint conversations and laughter of students as they walk to class, faint sounds from a nearby construction site, distant rumble of traffic, the distant droning of an airplane lazily floating through the april sky. From time to time you will also hear the well known "beep. . . Beep. . . . . Beep. . . . " of a piece of heavy equipment backing up. However, despite all of the dominating background of man and his machines, nature comes through. Sincei was sitting on the edge of a fairly large woods which sits in the center of all of the concrete and glass and steel, the sweet singing of birds lasts throughout much of this recording. Equipment used: zoom h4n recorder using the internal stereo microphones set on 180 degrees for the greatest sound capture.

Punching in a code.

Open microwave, place plate, close door, choose time, microwave, beeps, open door, retrieve plate, place plate on counter.

Noise of a big building-lot. You hear constant noise of the engine of an excavator and "beeps" when it is moving. In the background you hear a kind of drill machine or milling machine from time to time. Recorded with a zoom h1.

To heat a cup of water for instant coffee, one must open and close the door, set the run time and then remove the cup. I spared you the 66 second wait and the sound of the cat scratching in the litter box nearby.

I recorded this for an animated sequence i was doing that involved a bucket truck. I recorded a truck parked in a garage starting its motor, pulling out of the building, driving back into the building, stopping, hitting the air brakes and idling, backing up with backing beeps, idling again, and then honking its horn while pulling back out of the building. The truck circles the building again, pulls back in, hits the air brakes one more time and then cuts the motor.

Swedish påtagåg (train) arriving at hyllie station in sweden. Stays for at long time on the platform while you can hear "beeps". Finally, around 2. 29, there's a speaker announcement of the "øresundstog" departur. Recorded with zoom h6 in stereo.

Recorded in my dad's bedroom with lifecam hd3000 webcam. This is a much better recording than my previous oxygen concentrator file, as i hauled my desktop into the bedroom at the other end of the apartment where the machine now is, when i was home alone. The webcam is on the bed about 3 or 4 feet from the machineat the beginning of the file you hear me flip the big switch and the machine comes on with a long on beep and thumps. I edited it to start then. At 00:1. 8 what i suspect is the water pump comes on, though i may be wrong. That's when the gurgling starts though. The machine has a small reservoir for distilled water to moisten the airflow. A cup or two lasts several daysyou'll hear various hisses and thumps in a 15. 6 second cycle as it runs. At 03:03 i flip the big switch to shut the machine off, and it bubbles and gurgles away for the rest of the file, as water i assume slowly perculates back into the reservoir, the bubbling getting quieter and quieter until it doesn't even sound like bubbling anymore, until it finally ticks to a stop. At 03:16 you hear me step as i get my foot loose from the mic cord lol. At 04:13 the furnace shuts down as a car finishes going by outside in the bass register, faint traffic noises and the furnace being the only background noises you'll hear aside from my moving around a couple times, and a faint bluejay at the end. At about 07:00 you can barely hear the machine anymore, but i could hear a faint ticking with my own ears. At 07:04 the furnace comes back on. At 07:08 you'll hear a bluejay faintly calling outside and a car going by outside after, which finishes the file at 07:20. I edited out my walking to the computer to shut the recording down. From wikipediaoxygen concentrators typically use pressure swing adsorption technology and are used very widely for oxygen provision in healthcare applications, especially where liquid or pressurised oxygen is too dangerous or inconvenient, such as in homes or in portable clinics. Oxygen concentrators are also used to provide an economical source of oxygen in industrial processes, where they are also known as oxygen gas generators or oxygen generation plants. Oxygen concentrators utilize a molecular sieve to adsorb gasses and operate on the principle of rapid pressure swing adsorption of atmospheric nitrogen onto zeolite minerals and then venting the nitrogen. This type of adsorption system is therefore functionally a nitrogen scrubber leaving the other atmospheric gasses to pass through. This leaves oxygen as the primary gas remaining. Psa technology is a reliable and economical technique for small to mid-scale oxygen generation, with cryogenic separation more suitable at higher volumes and external delivery generally more suitable for small volumes. [1]at high pressure, the porous zeolite adsorbs large quantities of nitrogen, due to its large surface area and chemical character. After the oxygen and other free components are collected the pressure drops which allows nitrogen to desorb. An oxygen concentrator has an air compressor, two cylinders filled with zeolite pellets, a pressure equalizing reservoir, and some valves and tubes. In the first half-cycle the first cylinder receives air from the compressor, which lasts about 3 seconds. During that time the pressure in the first cylinder rises from atmospheric to about 1. 5 times normal atmospheric pressure (typically 20 psi/138 kpa gauge, or 1. 36 atmospheres absolute) and the zeolite becomes saturated with nitrogen. As the first cylinder reaches near pure oxygen (there are small amounts of argon, co2, water vapour, radon and other minor atmospheric components) in the first half-cycle, a valve opens and the oxygen enriched gas flows to the pressure equalizing reservoir, which connects to the patient's oxygen hose. At the end of the first half of the cycle, there is another valve position change so that the air from the compressor is directed to the 2nd cylinder. Pressure in the first cylinder drops as the enriched oxygen moves into the reservoir, allowing the nitrogen to be desorbed back into gas. Part way through the second half of the cycle there is another valve position change to vent the gas in the first cylinder back into the ambient atmosphere, keeping the concentration of oxygen in the pressure equalizing reservoir from falling below about 90%. The pressure in the hose delivering oxygen from the equalizing reservoir is kept steady by a pressure reducing valve. Older units cycled with a period of about 20 seconds, and supplied up to 5 litres per minute of 90+% oxygen. Since about 1999, units capable of supplying up to 10 lpm have been available.